Biomarkers for myocardial ischemia

ABSTRACT

This invention relates, e.g., to a method for determining if a subject has myocardial ischemia, comprising (a) providing a blood sample obtained from a subject suspected of having myocardial ischemia; (b) determining in the sample the amount of one or more of the following proteins: (i) Lumican and/or (ii) Extracellular matrix protein 1 and/or (iii) Carboxypeptidase N; and (c) comparing the amount(s) of the protein(s) to a baseline value that is indicative of the amount of the protein in a subject that does not have myocardial ischemia, wherein a statistically significantly increased amount of the protein(s) compared to the baseline value is indicative of myocardial ischemia. Other proteins indicative of myocardial ischemia are also described, as are methods for treating a subject based on a diagnostic procedure of the invention, and kits for carrying out a method of the invention.

This application is a U.S. national stage of PCT/US2009/045168 and claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application Ser. No. 61/128,686, filed May 23, 2008, each of which is entirely incorporated herein by reference.

BACKGROUND INFORMATION

Coronary heart disease is the most common single cause of death in the western world, representing about 20% of all deaths. This is equivalent to about 2 million deaths in Europe per year or four people per minute. In the US, over 8 million people exhibit acute (chest pain) symptoms in the Emergency Department (ED) of hospitals, with 1.5 million individuals having confirmed acute coronary symptom (ACS) events, accounting for 500,000 short term deaths. In patients presenting to the emergency room with chest pain, fewer than 15% are ultimately diagnosed as having ischemia or acute myocardial infarction (MI). Currently, blood tests for the cardiac specific isoform of troponin I or troponin T (TnI or TnT, respectively) are generally used for the diagnosis of acute myocardial infarction (due to cardiac muscle (cell) death). Creatine kinase (CK) MB and myoglobin can also be used, but are considered to be less specific for cardiac injury. However, although these cardiac biomarkers can identify patients with even small amounts of myocardial necrosis, there is an earlier time point in which the heart is in ischemia but is not yet in necrosis, and the diagnosis of cardiac ischemia in the absence of necrosis cannot currently be made with accuracy.

It would be useful to be able to identify subjects in this diagnostic window (having non-necrotic ischemia). Such a diagnostic tool would be of great value for triage in the emergency department. For example, it would allow earlier intervention, including earlier perfusion, to allow increased salvage of the injured myocardium; and it would prevent unnecessary admittance to the hospital of patients with non-cardiac chest pain. Furthermore, such an assay could delay therapy in subjects who do not exhibit diagnostic electrocardiographic (ECG) changes, and could help to improve the accuracy of current provocative tests for ischemia, such as exercise stress testing. The sooner intervention can be carried out, the less cardiac damage will occur. Reduced damage is correlated with an increase in long term survival.

DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic representation of protein spot attrition due to stringent criteria, based on a cohort that underwent atrial pacing to induce demand on the heart such that the blood flow was inadequate, thereby potentially causing myocardial ischemia. Blood samples were drawn from the coronary sinuses of individuals subjected to atrial pacing. The change in lactate acid level was an indication of induced ischemia, while the detection of cTnI or cTnT was indicative of cardiac necrosis. Those subjects that did not exhibit any change in lacate acid level or cTnT/cTnT were considered controls.

FIG. 2 shows a 2DE gel image showing two spots that are elevated in necrosis individuals. Serum samples were initially depleted of immunoglobins (IgG) and albumin, then separated based on pI and MW using gel electrophorisis. The majority of the spots did not change in all of the individuals subjected to atrial pacing. The graphs on the right show the spot volume in all three necrosis individuals. For both spots, 2 out of 3 were increased for those individuals which had cTnI detected after atrial pacing in their coronary sinus blood samples.

FIG. 3 shows 1DLC fractions strategy used in MS analysis. Samples were depleted of immunoglobins (IgG, IgM and IgA) and albumin, then separated based on hydrophobicity (Reversed phase high performance liquid chromatography, RPLC, 1DLC). The number of unique peptides/protein observed, and the number of times observed and protein coverage are semi-quantitative, because each domain will comprise the same protein species, although potentially differing in amounts.

FIG. 4 shows the number of peptides observed vs. the number of spectra count for all individuals and all time points obtained by 1DLC (hydrophobicity, RPLC—MS run 1).

FIG. 5 schematically illustrates the overlap between the three different proteomic methods used: 2DE, 1DLC and 2DLC. For 2DLC, the serum samples were depleted of immunoglobins (IgG, IgM and IgA) and albumin, then separated based on chromatographic focusing (pH from 8.5 to 4.0) and reversed phase HPLC (1DLC). Fractions from areas found to be different in the 2DLC were analyzed by MS. Differences in spectral counting and or number of peptides observed were included as changed. Superscripts 1-6 refer to the following:

1. Two additional proteins were observed in each protein spot. Caspase 14 was observed to change in AMI (individual) 15 and by 1DLC for individuals (1-10) that underwent atrial pacing

2. Most stringent—greater than 2 fold increase (3.2) in ⅔ ischemia or AMI patients as well as fluctuation in other individuals

3. Reduced stringency (fold change reduced (2.2)) greater than 1.5 fold change

4. Reduced stringency—greater than 2 fold increase in ⅔ ischemia or AMI patients but fluctuates with individuals

5. LPLNECA-1=isoform 1 of Long palate, lung and nasal epithelium carcinoma-associated protein 1

6. LMW and HMW kinnogen-1 were detected but it was the bradykinin peptide that was elevated

FIG. 6 shows schematically the collection during valve replacement. In this chorot, coronary sinus samples were obtained from individuals who underwent induced ischemia due to stopping of the heart (with cardioplegia) during valve replacement. Coronary sinus samples were obtained and depleted prior to being separated by 1DLC (as outlined above). Proteins found to be increased with ischemia in the majority of individuals were considered first tier. However, it must be recognized that lower abundant proteins may only be observed in a few patients due to inherent detection limits of this type of MS analysis. These proteins might be actually elevated in many patients and just not observed with this approach.

FIG. 7 shows a box plot of cTnI at all time points for the individuals that under went valve replacement. Note that all individuals eventually had detectable cTnI/cTnT in their serum, indicating necrosis. However, at the time points at which de novo discovery was undertaken, none of the individuals had detectable cTnT or cTnI. This shows that all were ischemic at the time of study.

DESCRIPTION

The present inventors have identified a number of protein markers for cardiac (myocardial) ischemia, including non-necrotic cardiac (myocardial) ischemia.

Three different types of protein analysis were performed to identify these markers, in order to cover as broad a base as possible of proteome coverage, e.g. to allow the enhanced detection of isoforms and of post-translational modifications (PTM). These types of analysis were two-dimensional electrophoresis (2DE, separating proteins based on pI and molecular weight), two-dimensional liquid chromatography (2DLC, separating proteins based on pI and hydrophobicity) and one-dimensional liquid chromatography (1DLC, separating proteins based on hydrophobicity). Note that the starting pH differs between 2DLC and 1DLC: pH 8.5 and 2.3, respectively. Two different cohorts were analyzed—increased metabolic demand (cohort 1) and reduced supply (cohort 2).

In a first study, ischemia was induced in a first cohort of subjects by metabolic demand: subjects were stimulated by atrial pacing, which makes the heart beat faster and induces ischemia, as indicated by an increase in lactate, and potentially myocardial necrosis (based on detection of cTnI or cTnT in blood). In some cases, individuals did not exhibit any increase in lactate or detectable cTnI/cTnT. These latter individuals were considered controls. Multiple serum samples were obtained for each individual. Differences between baseline (prior to pacing) and those at peaking pacing and up to 60 minutes after were analyzed. Those proteins that were elevated compared to the baseline in the majority of ischemic or necroiss individuals (and not elevated in controls) were considered to be of interest.

This procedure mimics naturally occurring metabolic cardiac events, such as ministrokes, that might precede a full MI. Ischemia is a heterogeneous group of conditions, resulting from different underlying mechanisms, such as demand and supply limitation. We have “mimicked” these two conditions in the different cohorts used in the analysis. Thus, these cohorts are expected to reflect markers that are overexpressed in subjects suffering from ischemia resulting from a variety of such underlying mechanisms. Samples from demand (atrial pacing) were evaluated by 2DE, 2DLC and 1DLC.

In a second study, ischemia was induced in a second cohort by coronary blockage: subjects undergoing valve replacement surgery exhibited ischemia because of blood loss during the procedure. This procedure mimics naturally occurring events in which ischemia is induced by coronary blood vessel blockage. This cohort was evaluated only by 1DLC, the procedure which provided a comparison to the most useful results with the first cohort. Those proteins found to be altered in both cohorts are considered to be “tier one” markers, although strong hits in either cohort may also be considered to be prime candidate markers.

The results of the studies with these two cohorts are summarized in Table 13. Taken together, these studies show that three proteins are implicated as the most highly correlated markers (sometimes referred to herein as “first tier” markers, as they are observed to be elevated in both cohorts) for ischemia, regardless of the cause of the ischemia: Lumican; Extracellular matrix protein 1 (ECM-1); and Carboxypeptidase N (e.g., the catalytic chain).

Three markers in addition to Lumican, ECM-1 and Carboxypeptidase N are implicated as first tier markers for at least subjects similar to those in the first cohort: Angiogenin; Semenogclin (e.g., isoforms 1 and 2); and Long palate, lung and nasal epithelium carcinoma-associated protein 1 (LPLNECA-1) (e.g., isoform 1; isoforms 2-4 are also present, but the method of analysis employed in this study, although it supports isoform 1, cannot distinguish among the four isoforms, which are splice variants, so isoforms 2-4 cannot be ruled out due to sequence homology).

Ten markers in addition to Lumican, ECM-1 and Carboxypeptidase N are implicated as first tier markers for at least subjects similar to those in the second cohort: Perioxiredoxin isoform 2; 5100 isoforms A7, A8 and A9 (other S100 isoforms were detected and not observed to be altered); Sortilin-related receptor; Catalase; Low density lipoprotein receptor related proteins 1 and 2; and Syntaxin 3.

In addition to these first tier markers, Table 13 lists some “second tier” markers which can also be used for identifying subjects similar to those in both cohorts I and II; in cohort I; or in cohort II. These include, e.g., Alpha-2-HS-glycoprotein; Galectin-7; Hornerin; Proteoglycan-4; Profilaggrin (also called Filaggrin); Vitamin D binding protein; C4b-binding protein alpha chain; Thyroxine binding globulin; Alpha-2-glycoprotein 1, zinc; protease, serine 3; Caspase 14; Desmogelin; Kininogen-1 (we observed the peptide for the intact protein, but our data cannot distinguish between changes to the LMW or HMW, which could also be present); Hepatocyte growth factor like protein; Hepatocyte growth factor activator; and Insulin like growth factor protein 6.

In some embodiments of the invention, it is desirable to distinguish between subjects whose ischemia is induced by metabolic causes (similar to the subjects of cohort I), and subjects whose ischemia is induced by coronary blood vessel blockage (similar to the subjects of cohort II), because different treatment methods can be used for the two classes of subjects. The markers of the invention can be used to make such distinctions.

This invention relates, e.g., to a method for determining if a subject has myocardial ischemia, comprising measuring in a sample from the subject the amount of at least one of the following proteins, compared to a baseline value:

a) Lumican and/or

b) Extracellular matrix protein 1 and/or

c) Carboxypeptidase N,

wherein a significant amount (e.g., at least a statistically significant amount) of over-expression of the protein(s) compared to the baseline value is indicative of myocardial ischemia (e.g., indicates that the subject has, or is likely to have, myocardial ischemia). The amount of expression may be determined for any combination of 1, 2, or all 3, of these proteins, and the determinations can be conducted simultaneously, or in any order.

Another aspect of the invention is a method for identifying subjects that have myocardial ischemia that is induced by a metabolic-induced ischemic event [due to a metabolic limitation, in which the heart is unable to meet metabolic need; (excessive) metabolic demand], comprising determining in the sample from the subject the amount, compared to a baseline value, of at least one of proteins a), b), c) above,

d) Angiogenin,

e) Semenogelin, and/or

f) Long palate, lung and nasal epithelium carcinoma-associated protein 1. The amount of expression may be determined for any combination of 1, 2, 3, 4, 5, or 6 of these proteins, and the determinations can be conducted simultaneously, or in any order.

Another aspect of the invention is a method for identifying subjects that have myocardial ischemia that is induced by coronary blood vessel blockage, which limits the supply of blood, comprising determining in the sample from the subject the amount, compared to a baseline value, of at least one of proteins a), b), c) above,

g) Syntaxin,

h) Perioxiredoxin isoform 2,

i) S100 isoform A7,

j) S100 isoform A8,

k) S100 isoform A9,

l) Sortilin-related receptor

m) Catalase

n) Low density lipoprotein receptor related protein 1, and/or

o) Low density lipoprotein receptor related protein 2. The amount of expression may be determined for any combination of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 of these proteins, and the determinations can be conducted simultaneously, or in any order.

In addition to the proteins noted above, one of more of the “second tier” proteins indicated in Table 13 can also be measured. A skilled worker will recognize which of these markers are indicative of a cohort I-type of condition, and which are indicative of a cohort II-type of condition.

Another aspect of the invention is a method for determining if a subject has myocardial ischemia, comprising determining in a sample from the subject the amount, compared to a baseline value, of at least one (e.g., at least four) of at least proteins a)-p) as noted above. The amount of expression may be determined for any combination of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15 of these proteins; and the determinations can be conducted simultaneously, or in any order.

In a method of the invention, a determination that increasing numbers of protein markers of the invention are overexpressed in a subject can further indicate that the subject has (or is likely to have) myocardial ischemia.

A method as above may further comprise measuring in the sample the amount of one or more other markers that have been reported to be diagnostic of cardiac necrosis, including cardiac specific isoforms of troponin I (TnI) and/or troponin T (TnT) (although CK-MB, myoglobin, have been used in the past, cTnI and cTnT are the current gold standards), wherein a significant increase (e.g., at least a statistically significant increase) of the one or more markers further is further indicative that the subject has myocardial ischemia.

As noted above, ischemia is a heterogeneous condition caused by a variety of underlying mechanisms. Even if a single marker of the invention is capable of detecting a subject having ischemia resulting from a particular mechanism, it is possible for some markers that the marker is also upregulated in a disease other than myocardial ischemia. In such a case, it would be desirable to screen for upregulation of at least one additional marker that is associated with ischemia caused by a different underlying mechanism. The column labeled “Function” in Table 13 shows that some of the markers of the invention can be divided into particular groups on the basis of their functions. A skilled worker, studying this table, could readily identify markers associated with different mechanisms. In one embodiment of the invention, markers associated with 2, 3, 4 or more underlying mechanisms can be tested together in an assay of the invention.

Another aspect of the method is a method for deciding how to treat a subject suspected of having myocardial ischemia, or a subject that is at high risk for having myocardial ischemia, comprising determining by a method as above if the subject has (or is likely to have) myocardial ischemia and, (1) if the subject is determined to have (or to be likely to have) myocardial ischemia, deciding to treat the subject aggressively [such as with angioplasty (mechanical widening in opening blood vessels), treating with an anti-thrombolysis agent or, if possible, with percutaneous coronary intervention (PCI, or TPA), or undergoing coronary bypass surgery to replace the injured/blocked coronary artery], or (2) if the subject is determined not to have (or not to be likely to have) myocardial ischemia, deciding to treat the subject non-aggressively [such as with asprin and/or thrombolysis (e.g., TPA), with periodic monitoring to ensure no future MI events, or by recommending changes in life style. This method can be used to confirm that a subject does not have ischemia (especially if myocardial ischemia is not detectable by cTnI or cTnT elevation), and thus to allow the subject to be released from hospital care.]

Another aspect of the invention is a method for treating a subject suspected of having myocardial ischemia, or a subject that is at high risk for having myocardial ischemia, comprising determining by a method as above if the subject has (or is likely to have) myocardial ischemia and, (1) if the subject is determined to have (or to be likely to have) myocardial ischemia, treating the subject aggressively, as indicated above, or (2) if the subject is determined not to have (or not to be likely to have) myocardial ischemia, treating the subject non-aggressively, as indicated above.

Another aspect of the invention is a kit for detecting the presence of ischemia in a subject, comprising reagents for detecting the amounts of at least one (e.g., any combination of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15 of at least proteins a)-o) as noted above.

This invention relates, e.g., to a method for determining if a subject has myocardial ischemia, comprising

(a) providing a sample obtained from a subject suspected of having myocardial ischemia;

(b) determining in the sample the amount of at least one of at least proteins a)-p) as noted above (e.g., any combination of 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15) of the proteins); and

(c) comparing the amount(s) of the protein(s) to a baseline value that is indicative of the amount of the protein in a subject that does not have myocardial ischemia,

wherein an increased amount (e.g., a statistically significantly increased amount) of the protein(s) compared to the baseline value is indicative of myocardial ischemia.

In one embodiment of the invention, the amount(s) of the protein(s) is compared over time to the baseline value and/or to levels known to be associated with necrosis. The kinetic rise and fall of combinations of proteins is indicative of impending myocardial ischemia (or other cardio and vascular events, such as stroke. A method of the invention can also be used to determine risk in subjects (patients) with stable or unstable angina.

A sample which is “provided” can be obtained by the person (or machine) conducting the assay, or it can have been obtained by another, and transferred to the person (or machine) carrying out the assay.

By a “sample” (e.g. a test sample) from a subject meant a sample that might be expected to contain elevated levels of the protein markers of the invention in a subject having myocardial ischemia. Many suitable sample types will be evident to a skilled worker. In one embodiment of the invention, the sample is a blood sample, such as whole blood, plasma, or serum (plasma from which clotting factors have been removed). For example, peripheral, arterial or venous plasma or serum can be used. In another embodiment, the sample is urine, sweat, or another body fluid into which proteins are sometimes removed from the blood stream. In the case of urine, for example, the protein is likely to be broken down, so diagnostic fragments of the proteins of the invention can be screened for. In another embodiment, the sample is cardiac tissue, which is harvested, e.g., after a heart transplant or the insertion of a pacemaker or defibrillator. Methods for obtaining samples and preparing them for analysis (e.g., for detection of the amount of protein) are conventional and well-known in the art. Some suitable methods are described in the Examples herein or in the references cited therein.

A “subject,” as used herein, includes any animal that has, or is suspected of having, myocaridal ischemia. Suitable subjects (patients) include laboratory animals (such as mouse, rat, rabbit, guinea pig or pig), farm animals, sporting animals (e.g. dogs or horses) and domestic animals or pets (such as a horse, dog or cat). Non-human primates and human patients are included. For example, human subjects who present with chest pain or other symptoms of cardiac distress, including, e.g. shortness of breath, nausea, vomiting, sweating, weakness, fatigue, or palpitations, can be evaluated by a method of the invention. About ¼ of MI are silent and without chest pain. Furthermore, patients who have been evaluated in an emergency room or in an ambulance or physician's office and then dismissed as not being ill according to current tests for infarction have an increased risk of having a heart attack in the next 24-48 hours; such patients can be monitored by a method of the invention to determine if and when they begin express markers of the invention, which indicates that, e.g., they are beginning to exhibit ischemia. Subjects can also be monitored by a method of the invention to improve the accuracy of current provocative tests for ischemia, such as exercise stress testing. An individual can be monitored by a method of the invention during exercise stress tests of Dobutamine stress tests to determine if the individual is at risk for ischemia; such monitoring can supplement or replace the test that is currently carried out. Athletes (e.g., humans, racing dogs or race horses) can be monitored during training to ascertain if they are exerting themselves too vigorously and are in danger of undergoing an MI.

In another embodiment of the invention, the method is used as a screen in order to identify a drug (or to improve a cardioplegic solution) that protects the heart from ischemia and necrosis. The detection of one or more of the proteins of the invention in blood (or media if cell culture is used) is indicative of ischemia, and the quantity of the protein(s) is indicative of the severity of the ischemia.

The properties and amino acid sequences of the proteins of the invention are well-known and can be determined routinely, as well as downloaded from various known databases. See, e.g., the database, International Protein Index (IPI) at the world wide web site, ebi.ac.uk/IPI/xrefs.html. A summary of some properties of some of the proteins discussed herein, including their IPI ID number and amino acid sequences, is provided in Examples II and IV. This information is accurate as of the date of filing of this application. However, some of this information, including the sequences, is routinely updated (e.g. to correct mistakes in the previous entries), so updated (corrected) information about the proteins is included in this application. Information provided in the IPI database is incorporated by reference in the present application.

Although much of the data presented in the Examples herein are directed to particular forms of proteins of interest (or peptides thereof), it will be evident to a skilled worker that a variety of forms of these proteins may be indicative of the presence of myocardial ischemia in a subject. For example, the protein may be an intact, full-length protein. If a protein undergoes processing naturally (e.g., is converted from a pre-pro-hormone to a pro-hormone to a fully processed hormone; the N-terminal methionine is cleaved off; the signal sequence is removed, often accompanied by a post-translational modification, such as acetylation; etc.), any of these forms of the protein are included in the invention. Furthermore, in some instances, a protein of the invention may be broken down or degraded (e.g., proteins that are found in the urine). In such a case, an investigator can determine the level of one or more of the fragments or degradation products. A “diagnostic protein fragment,” as used herein, is a fragment that is unique to the protein being identified, as detected by the assay. For example, a diagnostic fragment is recognized specifically by an antibody used to detect the full-length protein. Certain isoforms or post translational modifications (PTM) may also be encompassed by the invention. For example, the inventors have obtained data indicating PTM for C4b binding proteins; protease, serine; 3 alpha-2-glycoprotein 1; and zinc caspase 14.

The proteins and combinations of proteins discussed herein are sometimes referred to herein as “proteins (or protein markers) of the invention.”

A variety of tests that have been used to detect myocardial events (particularly late occurring events, such as necrotic myocardial ischemia). These include, e.g., determining the levels of cardiac specific isoform(s) of troponin I (TnI) and/or troponin T (TnT), CK-MB (Creatine Kinase-MB), or myoglobin, although only the former two are the current gold standard. CK MB and myoglobin are not cardiac-specific. However, none of these markers is completely satisfactory for the detection of myocardial ischemia. For example, they fail to detect early stages of heart disease, such as non-necrotic myocardial ischemia. The new markers described herein can be used in conjunction with these types of assays.

When the values of more than one protein are being analyzed, a statistical method such as multi-variant analysis or principal component analysis (PCA) is used which takes into account the levels of the various proteins (e.g., using a linear regression score). For verification, we will use either immunoassay or multiple reaction monitoring (MRM, a MS-based targeted method that quantifies peptides that are unique to the protein of interest) on individuals (control, ischemia and MI).

In some embodiments, it is desirable to express the results of an assay in terms of an increase (e.g., a statistically significant increase) in a value (or combination of values) compared to a baseline value.

A “significant” increase in a value, as used herein, can refer to a difference which is reproducible or statistically significant, as determined using statistical methods that are appropriate and well-known in the art, generally with a probability value of less than five percent chance of the change being due to random variation. In general, a statistically significant value is at least two standard deviations from the value in a “normal” healthy control subject. Suitable statistical tests will be evident to a skilled worker. For example, a significant increase in the amount of a protein compared to a baseline value can be about 50%, 2-fold, or more higher. A significantly elevated amount of a protein of the invention compared to a suitable baseline value, then, is indicative that a test subject has myocardial ischemia (indicates that the subject is likely to have myocardial ischemia). A subject is “likely” to have myocardial ischemia if the subject has levels of the marker protein(s) significantly above those of a healthy control or his own baseline (taken at an earlier time point). The extent of the increased levels correlates to the % chance. For example, the subject can have greater than about a 50% chance, e.g., greater than about 70%, 80% 90%, 95% or higher chance, of having the ischemia. In general, the presence of an elevated amount of a marker of the invention is a strong indication that the subject has ischemia.

As used herein, a “baseline value” generally refers to the level (amount) of a protein in a comparable sample (e.g., from the same type of tissue as the tested tissue, such as blood or serum), from a “normal” healthy subject that does not exhibit myocardial ischemia. If desired, a pool or population of the same tissues from normal subjects can be used, and the baseline value can be an average or mean of the measurements. Suitable baseline values can be determined by those of skill in the art without undue experimentation. Suitable baseline values may be available in a database compiled from the values and/or may be determined based on published data or on retrospective studies of patients' tissues, and other information as would be apparent to a person of ordinary skill implementing a method of the invention. Suitable baseline values may be selected using statistical tools that provide an appropriate confidence interval so that measured levels that fall outside the standard value can be accepted as being aberrant from a diagnostic perspective, and predictive of ischemia.

It is generally not practical in a clinical or research setting to use patient samples as sources for baseline controls. Therefore, one can use any of variety of reference values in which the same or a similar level of expression is found as in a subject that does not have myocardial ischemia.

It will be appreciated by those of skill in the art that a baseline or normal level need not be established for each assay as the assay is performed but rather, baseline or normal levels can be established by referring to a form of stored information regarding a previously determined baseline levels for a given protein or panel of proteins, such as a baseline level established by any of the above-described methods. Such a form of stored information can include, for example, a reference chart, listing or electronic file of population or individual data regarding “normal levels” (negative control) or positive controls; a medical chart for the patient recording data from previous evaluations; a receiver-operator characteristic (ROC) curve; or any other source of data regarding baseline levels that is useful for the patient to be diagnosed. In one embodiment of the invention, the amount of the proteins in a combination of proteins, compared to a baseline value, is expressed as a linear regression score, as described, e.g., in Irwin, in Neter, Kutner, Nachtsteim, Wasserman (1996) Applied Linear Statistical Models, 4^(th) edition, page 295.

In an embodiment in which the progress of a treatment is being monitored, a baseline value can be based on earlier measurements taken from the same subject, before the treatment was administered.

The amount of a protein can be measured using any suitable method. Some methods involve the use of antibodies, binding ligands, or mass spectrometry tagged peptides specific for a protein of interest. Antibodies suitable for use in assays of the invention are commercially available, or can be prepared routinely. Methods for preparing and using antibodies in assays for proteins of interest are conventional, and are described, e.g., in Green et al., Production of Polyclonal Antisera, in immunochemical Protocols (Manson, ed.), (Humana Press 1992); Coligan et al., in Current Protocols in Immunology, Sec. 2.4.1 (1992); Kohler & Milstein (1975), Nature 256, 495; Coligan et al., sections 2.5.1-2.6.7; and Harlow et al., Antibodies: A Laboratory Manual, page 726 (Cold Spring Harbor Laboratory Pub. 1988).

Any of a variety of antibodies can be used in methods of the invention. Such antibodies include, e.g., polyclonal, monoclonal (mAbs), recombinant, humanized or partially humanized, single chain, Fab, and fragments thereof. The antibodies can be of any isotype, e.g., IgM, various IgG isotypes such as IgG_(1′) IgG_(2a), etc., and they can be from any animal species that produces antibodies, including goat, rabbit, mouse, chicken or the like. The term, an antibody “specific for” a protein, means that the antibody recognizes a defined sequence of amino acids, or epitope in the protein. An antibody that is “specific for” a polypeptide refers to an antibody that binds selectively to the polypeptide and not generally to other polypeptides unintended for binding to the antibody. The parameters required to achieve such specificity can be determined routinely, using conventional methods in the art. Conditions that are effective for binding a protein to an antibody which is specific for it are well-known and conventional.

In one embodiment of the invention, antibodies specific for a (one or more) protein of the invention are immobilized on a surface (e.g., are reactive elements on an array, such as a microarray, or are on another surface, such as used for surface plasmon resonance (SPR)-based technology, such as Biacore), and proteins in the sample are detected by virtue of their ability to bind specifically to the antibodies. Alternatively, proteins in the sample can be immobilized on a surface, and detected by virtue of their ability to bind specifically to the antibodies. Methods of preparing the surfaces and performing the analyses, including conditions effective for specific binding, are conventional and well-known in the art.

Among the many types of suitable immunoassays are immunohistochemical staining, ELISA, Western blot (immunoblot), immunoprecipitation, radioimmuno assay (RIA), fluorescence-activated cell sorting (FACS), etc. Assays used in a method of the invention can be based on colorimetric readouts, fluorescent readouts, mass spectrometry, visual inspection, etc. Assays can be carried out, e.g., with suspension beads, or with arrays, in which antibodies or cell or blood samples are attached to a surface such as a glass slide or a chip.

In one embodiment, a tissue sample (e.g. a cardiac tissue sample) is stained with a suitable antibody in a conventional immunohistochemical assay for those proteins which are present in the myocardium. Note that it can be difficult to obtain human tissue unless an individual is undergoing surgery or a routine biopsy (e.g. following heart transplantation), and such subjects are likely to be ischemic to some degree.

Mass spectrometry (MS) can also be used to determine the amount of a protein, using conventional methods. Some typical such methods are described in the Examples herein. Relative ratio between multiple samples can be determined using label free methods (as done in the present Examples), based on spectral count (and the number of unique peptides and the number of observation of each peptide). In the Examples herein, we used a LTQ-Orbitrap LC/MS/MS instrument to obtain the data. Alternatively, quantitive data can be obtained using multiple reaction monitoring (MRM), most often carried out using a triple quadruple mass spectrometer. In this case, peptides that are unique to a given protein are selected in the MS instrument and quantified. Absolute quantification can be obtained if a known labeled synthetic peptide is used. For detailed methods see, e.g., Qin Fu and JE Van Eyk, in Clinical Proteomics: from diagnostics to therapy (Van Eyk JE and Dunn M, eds), Wiley and Son Press; Current Protocols in Molecular Biology, Preparation of Proteins and Peptides for Mass Spectrometry Analysis in a Bottom-Up Proteomics Workflow, Gundry et al., chapter 10, 2009, in press)

In general, molecular biology methods referred to herein are well-known in the art and are described, e.g., in Sambrook et al., Molecular Cloning: A Laboratory Manual, current edition, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., and Ausubel et al., Current Protocols in Molecular Biology, John Wiley & sons, New York, N.Y.

A detection (diagnostic) method of the invention can be adapted for many uses. For example, it can be used to follow the progression of cardiac ischemia. In one embodiment of the invention, the detection is carried out both before (or at approximately the same time as), and after, the administration of a treatment, and the method is used to monitor the effectiveness of the treatment. A subject can be monitored in this way to determine the effectiveness for that subject of a particular drug regimen, or a drug or other treatment modality can be evaluated in a pre-clinical or clinical trial. If a treatment method is successful, the levels of the protein markers of the invention are expected to decrease.

A method of the invention can be used to suggest a suitable method of treatment for a subject. For example, if a subject is determined by a method of the invention to be likely to have myocardial ischemia, a decision can be made to treat the subject with an aggressive form of treatment; and, in one embodiment, the treatment is then administered. Suitable aggressive treatment modalities include, for example, angioplasty (mechanical widening to open blood vessels); treating with an anti-thrombolysis agent or, if possible, with percutaneous coronary intervention (PCI, or TPA); or undergoing coronary bypass surgery to replace the injured/blocked coronary artery. Methods for carrying out such treatments are conventional and well-known. By contrast, if a subject is determined not to be likely to have myocardial ischemia, a decision can be made to adopt a less aggressive treatment regimen; and, in one embodiment, the subject is then treated with this less aggressive forms of treatment. Suitable less aggressive forms of treatment include, for example, treatment with asprin and/or agents that bring about thrombolysis (e.g., TPA); periodic monitoring to ensure no future MI events; or recommending changes in life style. A subject that does not have myocardial ischemia is thus spared the unpleasant side-effects associated with the unnecessary, more aggressive forms of treatment. By “treated” is meant that an effective amount of a drug or other anti-heart disease procedure is administered to the subject. An “effective” amount of an agent refers to an amount that elicits a detectable response (e.g. of a therapeutic response) in the subject.

One aspect of the invention is a kit for detecting whether a subject is likely to have myocardial ischemia, comprising one or more agents for detecting the amount of a protein of the invention. As used herein, the singular forms “a,” “an” and “the” include plural referents unless the context clearly dictates otherwise. For example, “a” protein of the invention, as used above, includes 2, 3, 4, 5 or more of the proteins. In addition, other markers for ischemia (e.g., as discussed elsewhere herein) can also be present in a kit. If mass spectrometry is to be used to measure protein levels, the following reagents can be included in the kit: known amounts of a labeled (e.g. stable isotope) peptide (synthetic or recombinant) standard for each peptide to be assessed, separately or combined into a single mixture containing all peptides; optionally, a different peptide standard for assessing reproducibility of the assay; and/or, optionally, dilutant and trypsin for preparation of the sample. If an antibody-based method is to be used to measure protein levels, the agents in the kit can encompass antibodies specific for the proteins. The kit may also include additional agents suitable for detecting, measuring and/or quantitating the amount of protein, including conventional analytes for creation of standard curves. Among other uses, kits of the invention can be used in experimental applications. A skilled worker will recognize components of kits suitable for carrying out a method of the invention.

Optionally, a kit of the invention may comprise instructions for performing the method. Optional elements of a kit of the invention include suitable buffers, containers, or packaging materials. The reagents of the kit may be in containers in which the reagents are stable, e.g., in lyophilized form or stabilized liquids. The reagents may also be in single use form, e.g., for the performance of an assay for a single subject. In one embodiment of the invention, the kit is a “home chest pain test kit,” that can be used to test blood, urine, or other body fluids for the presence (and/or level) of protein markers of the invention. Thus, a patient who has been released from an Emergency Department (ED) or a cardiac ward, but who is at risk over the next about 48 hours, can take the test over time at home and, if the test produces positive results, return to the ED.

In the foregoing and in the following examples, all temperatures are set forth in uncorrected degrees Celsius; and, unless otherwise indicated, all parts and percentages are by weight.

EXAMPLES Example I Identification of Novel Cardiac Biomarkers that are Rapidly Released into the Coronary Sinus in Response to Cardiac Ischemia, Even in the Absence of Detectable Myocyte Necrosis

A. Overview of the Studies

Rapid atrial pacing has been reported to produce reversible and controlled myocardial ischemia, as measured by a coronary sinus lactate concentration that rises above arterial lactate concentration, in approximately ⅔ of patients with fixed epicardial coronary artery disease (>70% diameter stenosis in at least one coronary artery). (Dehmer et al. (1983) Am Heart J 106, 114-24; Markham et al. (1983) Am J Cardiol 51, 1589-94). Therefore, in the experiments shown in this Example, atrial pacing was used as the human demand ischemia model.

In the studies shown in this Example, three types of protein analysis were conducted to identify protein markers of the invention. There is normally less than 40% overlap (e.g., 3-5) in the proteins observed between the different types of analysis platforms. This is because every protein is intrinsically different with respect to its pI, hydrophobicity and mass. Furthermore, post translational modifications (PTM) alter the intrinsic nature of the protein and thus may display quite different separation or enrichment characteristics. As such, the choice of technology or group of technologies should be dictated by the characteristics of the proteins targeted by the experimental question. In the case of biomarker discovery (and based on the lessons learnt from the biomarker, cTnI), multiple protein separation strategies should (and do) increase proteome coverage.

The present inventors and collaborators have found that the combination of intact protein separation technologies of 2DE (two-dimensional electrophoresis), 2DLC (two-dimensional liquid chromatography) and 1DLC (one-dimensional liquid chromatography) increases the proteome coverage while allowing enhanced detection of isoforms and PTM. 2DE of serum (and plasma) was optimized for separation by using pH 4-7 and 10% Bis-Tris gel (Graham et al. (20050) Proteomics 5, 2309-14; Fu et al. (2005) Proteomics 5, 2656-64), as were the liquid chromatography methods. The combination of chemical depletion and optimized 2DE conditions can achieve good reproducibility (˜20% CV) (Fu et al. (supra)). Liquid chromatography (LC) separates proteins based on one or more of their intrinsic properties: mass (size exclusion), isoelectric point (pI, chromatographic focusing or ion exchange), hydrophobicity (reversed phase) or affinity chromatography (bio-specificity). Our laboratory has optimized 2DLC combining chromatographic focusing and reversed phase HPLC with the commercial Beckman Coulter instrument, the Two-Dimensional Protein Fractionation (PF2D) system (McDonald et al. (2006) Mol Cell Proteomics 5, 2392-411; Sheng et al. (2006) Mol Cell Proteomics 5, 26-34; Stasna et al. Protein separation: Liquid chromatography, In “Proteomic and Genomic Analysis of Cardiovascular Disease” (eds. Van Eyk JE and Dunn M) 2008 Wiley and Son Press, page 241). Briefly, samples are loaded onto the first dimension column (ion exchange column) at pH 8.5 in presence of urea and detergent and separated based on pI by decreasing the pH to 4.0 (Graham et al. (2006) (supra). Proteins that are bound tightly to the column or have a pI below 4.0 are eluted using 1M salt. We found that including 20% isopropanol in the buffers can eliminate “artificial” binding of a subset of proteins to the first dimension. Fractions are collected throughout the chromatographic separation and each fraction is subsequently separated by reversed phase chromatography using a linear gradient composed of aqueous trifloroacetic acid (TFA), pH 2.3 and TFA/actronitrile, pH 2.3. The second dimension elution profile is monitored at 214 nm (peptide bonds) and is semi-quantitative. On average, fractions contain 1-100 proteins in each peak (McDonald et al. (2006); Graham et al. (2006) (both supra)). These samples can be further analyzed by electrophoresis (1DE or 2DE) or analyzed directly by mass spectrometry (MS). If so, due to the complexity of the reversed phase fractions they must undergo further online LC separation prior to MS. An overview outlining the process is summarized in Fu et al. (2008) (supra).

B. Cohort Information for Atria Pacing Human Model—Cohort I

1. Research Design

Patients >20 years old with stable exertional angina referred for cardiac catheterization were recruited Exclusion criteria were atrial fibrillation, valvular heart disease, prior coronary artery bypass surgery, depressed left ventricular systolic function, acute coronary syndrome, and/or left bundle branch block. As well, patients were excluded if they reported angina within 48 hours of the catheterization. 19 individuals were recruited. The study was approved by the Institutional Review Boards of UT Southwestern and Parkland Hospital. All patients have signed written informed consent.

A 7 or 8 Fr Gorlin catheter was advanced to the coronary sinus from the right brachial vein. Coronary sinus, peripheral arterial, and peripheral venous serum samples were obtained prior to start of the atrial pacing. The left atrium was paced at 20 beats/minute above the resting heart rate and this was increased every 3 minutes by 20 beats/minute until one of the following occurs: chest pain, AV block, or a heart rate of 160 beats/minutes is achieved. The patient was maximally paced at this rate for 3 minutes. At the end of the three-minute period, repeat blood samples were collected from the coronary sinus and peripheral artery. Repeat sampling from the coronary sinus was performed at 30 and 60 minutes after pacing termination.

TABLE 1 Timing line for serum sample collection Immediate 30 minutes 60 minutes Location Baseline post-pacing post-pacing post-pacing Coronary X X X X Sinus

Blood was immediately placed on ice and was transported to the processing center within 30 minutes of collection. Samples were centrifuged, serum (and plasma) separated, and specimens aliquoted into 100 μL tubes using an automated micropipette system. No samples were at room temperature for longer than 10 minutes. The longest duration between sample collection and freezing was less than one hour. Lactate and cardiac troponin T (TnT) was measured in heparinized plasma a (see table 2)

2. Cohort and Experimental Group Designation

The cohort was designated based on the following criteria:

-   -   1) Cases (n=19) Significant coronary artery disease (at least         one vessel with a diameter stenosis ≧70%) and coronary sinus         lactate >arterial lactate after pacing (data not shown).     -   2) Controls are individuals with no or little change in lactate         pre vs. post.     -   3) Moderate or severe ischemia: individuals with increase in         lactate and are cTnT negative.     -   4) Necrosis designation was for individuals with increase in         lactate and are cTnT positive.     -   5)

TABLE 2 coronary sinus values PATIENT age csLpre csLpost TnT-cs0 TnT-cs1 TnT-cs2 TnT-cs3 Definition 1 50 0.4 0.7 <0.01 <0.01 <0.01 <0.01 mI 2 40 0.8 0.6 <0.01 <0.01 <0.01 <0.01 C 3 60 0.7 0.7 <0.01 <0.01 <0.01 <0.01 C 4 56 0.8 1 <0.01 <0.01 <0.01 <0.01 mI 5 63 0.8 0.9 <0.01 <0.01 <0.01 <0.01 C 6 51 0.7 0.7 <0.01 <0.01 0.018 0.029 N 7 51 0.4 1.2 <0.01 <0.01 <0.01 <0.01 sI 8 52 0.3 0.4 <0.01 <0.01 <0.01 <0.01 C 9 45 0.6 0.6 <0.01 <0.01 NA NA C 10 56 0.7 1.3 <0.01 <0.01 <0.01 <0.01 sI 11 50 0.5 0.9 <0.01 <0.01 <0.01 <0.01 sI 12 47 0.3 0.5 <0.01 <0.01 <0.01 <0.01 mI 13 57 1.1 0.9 <0.01 <0.01 NA NA excluded 14 62 0.9 1 <0.01 <0.01 <0.01 <0.01 excluded 15 43 0.3 0.8 <0.01 <0.01 0.026 0.109 N 16 52 1.22 1.48 <0.01 <0.01 <0.01 0.041 N 17 47 COAG 0.28 <0.01 <0.01 <0.01 <0.01 excluded 18 47 0.23 0.46 <0.01 <0.01 <0.01 <0.01 mI 19 53 0.17 0.16 C Pre and post define samples taken at baseline and after maximum pacing Definition defines, control (c) as no change in lactate and TnT negative, ischemia (I) as increase in lactate and TnT negative and differentiated in to moderate (mI) or severe (sI); necrosis (n) TnT positive and excluded for LC analysis (but included for 2DE). C. 2-Dimensional Gel Electrophoresis Analysis 1. 2DE Cohort

All patients and all time points were analyzed.

2. 2DE Methods

Serum was depleted of IgG using protein G affinity chromatography and depleted of albumin using our in-house affinity/chemical depletion method (Fu et al. (2005) (supra). Protein concentration was determined using BCA assay (Pierce) for each depleted sample. 50 ug of each time point (baseline time point 1, 2 and 3) per individual was labeled with one of the three Cy dyes (Applied Biosystems Inc.). As well, a pool sample was created from equal amounts of each time point of a single patient sample. For each individual, equal amount of two labeled sample (two time points) were mixed with the pool sample and then separated simultaneously using optimized pH 4-7 gel, followed by 10% Bis-Tris SDS PAGE. The gels were then imaged on a fluorescent gel imager at the Cy3, Cy5 and Cy2 wavelengths. Subsequently, the gels were stained with silver to allow visualization for spot picking. Gel images were analyzed by Ludesi Inc (http://www.ludesi.com/). Gels were aligned, spots matched and quantified. For example, gel images were prepared for an individual that became ischemic or underwent necrosis with pacing. Comparisons were made between baseline and the other subsequent time points for each individual. To avoid a nondetected (zero) value 0.1 was added to all values.

3. Selection Criteria.

Selection criteria for 2DE was based on analysis of all individual in each group (induced ischemia and induced necrosis) and are as follows:

-   -   i) Equal or greater than 1.5 fold increase compared to time         point 0 (baseline).     -   ii) The spot volume was above (100 units) to allow protein         identification by mass spectrometry.     -   iii) The spot was resolved.     -   iv) The change in the profile remains above baseline once         elevated.     -   v) A changed in 3 out of the 3 or 2 out of the 3 individuals in         a designated group (induced ischemia or induced necrosis) at any         time point.         4. Results for 2DE

Approximately 1200 protein spots were resolved on each 2DE gel. Due to stringent criteria for cut offs, most protein spots were deemed not to change or biological variability was too great to be significant (FIG. 1, see breakdown). Caspase 14 and complement factor B (isoform 1) increased specifically in patients with necrosis while fibrinogen beta chain and desmoglein-1 increased in patients with severe ischemia and necrosis (table 3).

TABLE 3 summary of changes detected by 2DE observed at large moderate Protein name baseline control ischemia ischemia necrosis Caspase-14 yes 1 out of 5 1 out of 3 0 out of 4 2 out of 3 Isoform 1 of yes 1 out of 5 1 out of 3 0 out of 4 2 out of 3 Complement factor B Fibrinogen yes 2 out of 5 1 out of 3 2 out of 4 2 out of 3 beta chain Desmoglein- yes 2 out of 5 1 out of 3 2 out of 4 2 out of 3 1

The majority of proteins observed by 2DE, high abundant soluble proteins, do not change with induced ischemia or necrosis. Without wishing to be bound by any particular mechanism, Caspase 14 (IPI00013885) is proposed to be involved in the death receptor and granzyme B apoptotic pathways. It may act as a downstream signal transducer of cell death. Desmoglein-1 (IPI00025753) is a component of the cell desmosome junctions which are distinct plasma membrane domains. It has a single transmembrane domain. Desmosomes are the most common type of intercellular junction in vertebrate epithelial cells but found in other cell types. This protein is part of a complex comprising plakophilin 1, plakophilin 2, desmoplakin, desmoglein 1, desmoglein 4, plakoglobin and corneodesmosin. Other proteins of the desmosome complex as well as caspase 14 are found by 1DLC and 2DLC in a few individuals.

Information sheets summarizing some of the properties of these and other proteins discussed herein are provided as Example II.

D. 1DLC Work Flow

1. 1DLC Cohort

Each individual time sample outlined below (table 4) was analyzed using reversed phase HPLC. The control group samples were selected based on having similar prelacate concentrations compared to the two disease groups.

TABLE 4 1DLC Group designation Patient numbers Time points control 3, 5 0 and 1 ischemia 7, 10, 11 0, 1, 2, 3 necrosis 6, 15, 16 0, 1, 3 2. 1DLC Method

Serum was depleted using an affinity chromatography comprised of IgY antibodies specific for all forms of immunoglobins (IgG, IgA and IgM) and then depleted of albumin using our in-house affinity/chemical depletion method. This was done in order to reduce background of the chromatogram. Protein concentration was determined using BCA assay (Pierce) for each depleted sample. Samples were analyzed on the same 1DLC columns. 50 ug of each sample was run (in duplicate) using our optimized gradient. One set was used for mass spectrometric analysis; the other set was stored at −80° C. Fractions were collected into 96-well plates, stored at −80° C. until analyzed. Protein standard was run every morning to ensure good, consistent and reproducible performance of HPLC system. Extensive washing was carried out between runs to eliminate possible cross-over contamination. Chromatographic images were compared and regions/domains with acceptable intensities from each experimental sample were selected or combined (FIG. 5). Total 650 fractions (26 fractions per sample) were dried down, neutralized, and digested with trypsin. 50% of the digested sample was applied to the LC LTQ-Orbitrap MS.

For LC-MS/MS experiments on the LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.), peptides were dissolved in 6 μl resuspension buffer (4% acetonitrile in water with 0.1% formic acid). Samples (3 μl) were loaded onto a 75 um×10 cm BioBasic C18 column (New Objective, Wobum, Mass.). Peptides were eluted into an LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.) using an Agilent 1200 nano-LC system (Agilent, Santa Clara, Calif.). The HPLC gradient was 5% to 60% B (90% acetonitrile/water in 0.1% Formic acid) over 30 or 60 min depended on sample complexity. The mass spectrometer was operated in data-dependent mode in which every FT-MS scan (survey 350-2000 Da) was followed by MS/MS scans of the 5 most abundant ions.

All mass spectrometry data was analyzed according to a pipeline established and already used in our laboratory, designed to meet stringent criteria from the proteomics community. Data from the LTQ-Orbitrap was searched against the IPI databases where possible, using Sorcerer Sequest (Sagen, San Jose, Calif.). Search results were validated and analyzed using Scaffold (Proteome Systems, Portland, Oreg.). Protein identifications based upon a single peptide observation were handled carefully through manual inspection of the tandem MS (MS/MS) spectra, BLAST searching of the sequence to ensure it matches only the reported protein, requiring a minimum of 8 amino acids and a peptide probability score of >0.9.

Data analysis was based on the following: peptide redundancy removed, protein name redundancy removed, the number of unique peptides and number of observation for each peptide regardless of charge state (2+. 3+ or 4+) were determined for each protein. The protein was proposed to have a potential PTM if it was identified in multiple non-sequential domain/fractions. This was noted and all data regardless of the fraction was included for quantitation of the protein.

Data reanalysis was carried out using a version of the published algorithm for spectral counting (Old et al. (2005) Molecular and Cellular Proteomics 4.10, 1487-502) that added a 1.25 correction factor value to all numbers, in order to eliminate any zero values (non detectable values). The algorithm R_(p)=Log₁₀(Px+1.25)/(P0+1.25)+Log₁₀(TP0−P0+1.25)/(TPx−Px+1.25)) and R_(sc)=Log₁₀(SCx+1.25)/(SC0+SCx+1.25)+Log₁₀(TSC0−SC0+1.25)/(TSCx−SCx+1.25), where R_(p) is the Log₁₀ ratio of number of unique peptides between time points 0 and x, R_(sc) is the Log₁₀ ratio of spectral counts between time points 0 and x, P0 or Px is the number of unique peptides or at baseline (0) or another time point (x) for the specific protein of interest. TP0 or TPx is the number of all unique peptides for the complete data set for that individual at that specific time point (0 or x). SC0 and SCx are the spectral counts at time points 0 and x for the protein. TSC0 and TSCx are the total number of spectral counts in the experiment at time points 0 and x. There is a linear correlation between number of peptides observed and the spectra count (under 70 peptides/Protein). However, for very abundant protein with 100's of peptides and observations the relationship is more non-linear. A cut off of 0.3 (2 fold) was used to indicate a change.

3. Duplicate MS Analysis

Two independent MS analyses were done on each LC fraction. In both cases, LC fractions were stored (−80° C.) following an independent LC separation of the intact proteins. Image analysis was carried out between the various LC runs to match the fractions as closely as possible. However, the fractions analyzed were not completely identical due to variation in the LC run and exact timing of the fraction collection. The stored fractions were dried down, neutralized and digested with trypsin. The digested sample was applied to the LC LTQ-Orbitrap MS and number of peptides and spectra count were determined (table 5). The total number of peptide and counts for each time points is shown in table 6. This is taken into account when calculating change.

TABLE 5 MS replicate on frozen intact protein sample cohort I, two protein LC runs, separated digestion and MS run sample: AMI-15-003 (F = fraction number) # peptides # peptides # peptides # peptides F1 + 2 + 3 + F1 + 2 + 3 + F15 + F15 + # peptides # peptides Protein name 4-duplicate 4-original 16-duplicate 16-original F25-original F25-duplicate alpha-1 antiproteinase 1 2 20 25 16 16 alpha1-antichymotrypsin 0 0 1 8 7 6 alpha-1-microglobulin/bikunin 0 0 2 0 0 0 Alpha-2-macroglobulin 0 0 7 2 32 31 alpha-2-plasmin inhibitor 0 0 0 0 0 2 Angiotensinogen 0 0 0 0 2 13 Apolipoprotein A-I 2 0 9 7 13 15 apolipoprotein A-IV 0 0 5 4 2 10 Apolipoprotein C-I 0 0 2 3 0 0 apolipoprotein E 0 0 0 0 2 8 Beta2- Glycoprotein 0 2 0 0 0 0 B-factor, properdin 0 0 15 19 2 8 C9 complement protein 0 0 8 2 0 1 carboxypeptidase N 0 0 6 0 0 0 caspase 14 2 0 0 0 0 0 cathelicidin antimicrobial peptide 0 0 2 0 0 0 coagulation factor II (thrombin) 0 0 4 3 0 0 coagulation factor XIII B subunit 2 3 0 0 0 0 complement component 1, s 0 0 0 2 0 0 complement component 2 0 0 0 0 3 2 complement component 3 2 2 33 14 71 81 complement component 4 binding 0 0 3 0 0 0 protein, alpha chain complement component 5 0 0 0 0 0 5 complement component 7 0 0 3 5 0 0 complement component 8, alpha 0 0 3 3 0 0 complement component 8, gamma 0 0 3 6 0 0 complement component C4A 0 0 32 19 16 29 complement component C6 0 0 3 2 0 0 complement component C8 beta 0 0 1 9 0 0 chain complement factor H 17 20 9 7 1 3 complement factor I 0 0 4 0 0 0 dermcidin 2 2 0 0 0 0 filaggrin 2 1 0 0 0 0 0 gelsolin 0 0 13 3 0 5 hemopexin 0 0 5 2 0 0 histidine-rich glycoprotein 0 0 3 0 0 0 hornerin 2 0 0 0 0 0 hyaluronan binding protein 2 0 0 0 3 0 0 Insulin-like growth factor- 4 4 0 0 0 0 binding protein 3 Inter-alpha-trypsin inhibitor heavy 0 0 9 6 6 9 chain H1 Inter-alpha-trypsin inhibitor heavy 0 0 8 3 6 15 chain H2 Inter-alpha-trypsin inhibitor heavy 0 0 6 0 0 0 chain H3 Inter-alpha-trypsin inhibitor heavy 0 0 10 2 0 4 chain H4 kallikrein B, plasma (Fletcher 0 0 0 4 0 0 factor) 1 kininogen-1 0 0 1 2 0 0 leucine-rich alpha-2-glycoprotein 1 0 0 5 0 0 0 lumican 0 0 4 5 0 0 pigment epithelium-derived factor 0 0 0 0 10 0 precursor (PEDF) plasma protease (C1) inhibitor 0 0 0 0 0 3 amyloid P 0 0 6 2 0 0 profilaggrin 0 1 0 0 0 0 S100 calcium-binding protein A7 3 4 0 0 0 0 S100 calcium-binding protein A8 1 2 0 0 0 1 S100 calcium-binding protein A9 1 2 0 0 0 1 transferrin 0 0 13 18 7 10 transthyretin 0 0 6 6 0 0 vitronectin 0 0 2 2 0 0

TABLE 6 total number of peptide and spectra count in MS run 1 and 2 run 1 peptides run 1 run 1 run 1 run 1 run 1 run 2 run 2 run 2 run 2 run 2 run 2 sam- time counts peptides counts peptides counts peptides counts peptides counts peptides counts ple point 0 TP 0 TP 1 TP 1 TP 2 TP 2 TP 0 TP 0 TP 1 TP 1 TP 2 TP 2 A-15 976 10694 820 10527 767  9761 530  3005 770 4702 802 4621 A-16 715  9250 737  8615 682  7908 728  4724 709 4962 695 4683 run 1 time run 1 run 1 run 1 run 1 run 1 run 1 run 1 run 2 run 2 run 2 run 2 run 2 run 2 run 2 run 2 point 0 TP 0 TP 1 TP 1 TP 2 TP 2 TP 3 TP 3 TP 0 TP 0 TP 1 TP 1 TP 2 TP 2 TP 3 TP3 1-7 794 10673 788 10661 806 10806 828 10529 652 3880 654 3338 621 4336 715 3370 1-10 763 12629 810 11952 873 12868 894 12353 693 3398 589 3486 489 2904 746 3493 1-11 997 10783 830 11027 645 15836 830 10666 661 4501 604 4012 603 3865 595 3791 4. Criteria Selection for 1DLC

Selection criteria for 1DLC was based on analysis of all individuals in each group (induced necrosis or induced ischemia) and are as follows:

i) Changes in the number of unique peptides or the number of time each peptide was observed regardless of charge state (2+. 3+ or 4+) were compared to the equivalent protein (if observed) at time point 0. Changes are based on R_(p) or R_(sc) values of 0.30 or greater. The fold changes associated with these R values depend on the number of observations and range from 1:4 ratio (R=0.36 before total observation correction, 4 fold change) to a 300:600 (R=0.3001 before total observation correction, 2 fold change). The total observation correction will shift the R value depending on the different in size of the 2 sample groups and the proportion of observations for a the protein of interest relative to the entire sample. A 10% difference in sample size between the compared samples could increase or decrease the R value by 0.045ii)

ii) Changes in 2 out of the 3 or 3 out of the 3 individuals in a designated group (induced ischemia or induced necrosis) at any time point.

5. Results

Although the number of unique peptides observed between MS run 1 and 2 were similar, the number of peptide observations was reduced in the second run (Table 6). This did not overly affect the number of proteins observed except for the lower abundant proteins. There were 25 different serum samples analyzed, giving raise to 650 fractions being analyzed per MS analysis (1300 total MS runs). This resulted in, for both MS runs, over 41,000 unique peptides being identified, with these peptides observed over 410,600 times. Table 7 outlines the proteins that met the criteria above and whether they were observed to change by 2DLC.

An additional level of stringency was added in which the variation within an individual was taken into account. The first tier proteins are found consistently to remain elevated. These are highlighted in bold type. Those proteins with variation between patients or time points were ranked as second tier. Bradykinin peptide was also included (rather than kininogen, the parent protein which had a weaker correlation) based on reducing the fold change required to 1.5 fold. It was the only additional protein that met this weaker criterion. For details regarding the proteins see Example II.

TABLE 7 summary of protein changes observed by 1DLC up in Protein up in necrosis change ischemia 2 or 3 detected protein name accession 2 or 3 of 3 of 3 by 2DLC Alpha-2-HS- IPI00022431 yes glycoprotein precursor Angiogenin IPI00008554 yes Carboxypeptidase N IPI00010295 yes catalytic chain Extracellular matrix IPI00645849 yes protein 1 Galectin-7 IPI00219221 yes Hornerin IPI00398625 yes Isoform 1 of Long IPI00291410 yes palate, lung and nasal epithelium carcinoma-associated protein 1 Isoform 2 of IPI00414684 yes Semenogelin-1 Lumican IPI00020986 yes Profilaggrin IPI00654788 yes Thyroxine-binding IPI00292946 yes yes globulin Vitamin D-binding IPI00555812 yes protein Isoform LMW of IPI00215894 yes Kininogen-1 (specifically bradykinin) C4b-binding protein IPI00021727 yes yes alpha chain Proteoglycan-4 IPI00655676/ yes (isoforms A and D) E. 2-Dimensional Liquid Chromatography 1. 2DLC Cohort

Since 2DLC requires 2 mg of protein or greater for each analysis and the quantity of sample for the atria pacing cohort was limited so pooling was required for each group as outlined in table 8.

TABLE 8 2DLC pool Patient Group numbers designation pooled Time points analyzed control 3, 19, 9 0 (2 mg protein) 3, 19 3 (2 mg protein) ischemia 7, 10, 11 0 (2 mg protein) 7, 10, 11 1 (2 mg protein) 7, 10, 11 2 and 3 (equal amounts) (2 mg protein) necrosis 15, 16 0 and 1 (equal amounts) (1.9 mg protein) 15, 16 2 and 3 (equal amounts) (1.9 mg protein) 2. 2DLC Method

Serum was depleted using an affinity chromatography comprised of IgY antibodies specific for 3 major forms of immunoglobins (IgG, IgA and IgM) and then depleted of albumin using our in-house affinity/chemical depletion method. This was done in order to reduce background of the chromatogram. Protein concentration was determined using BCA assay (Pierce). Samples were analyzed on the same set of first and second dimension columns. 2 mg of sample from each time point were sequentially injected on the HPCF first dimension column, followed by HPRF second dimension separation. Fractions were collected into 96-well plates and stored at −80 C until analyzed. Extensive washing was carried out between runs to eliminate possible cross-over contamination.

Chromatographic images were compared and the same regions/domains from multiple-pH fractions were combined based on profile and previous identification. Fractions from high salt wash were analyzed individually without pooling. Total 315 fractions from 7 time points were dried down, neutralized, and digested with trypsin. 50% of the digested sample was applied to the LC LTQ-Orbitrap MS.

For LC-MS/MS experiments on the LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.), peptides from the digestion of LC fraction were resuspended in 6 μl resuspension buffer (4% acetonitrile in water with 0.1% formic acid). Samples (3 μl) were loaded onto a 75 um×10 cm BioBasic C18 column (New Objective, Woburn, Mass.). Peptides were eluted into an LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.) using an Agilent 1200 nano-LC system (Agilent, Santa Clara, Calif.). The HPLC gradient was 5% to 60% B (90% acetonitrile/water in 0.1% Formic acid) over 30 or 60 min dependent on sample complexity. The mass spectrometer was operated in data-dependent mode in which every FT-MS scan (survey 350-2000 Da) was followed by MS/MS scans of the 5 most abundant ions.

All mass spectrometry data was analyzed according to the pipeline established and already used in the Van Eyk laboratory, designed to meet stringent criteria from the proteomics community. Data from the LTQ-Orbitrap was searched against the IPI databases where possible, using Sorcerer Sequest (Sagen, San Jose, Calif.). Search results were validated and analyzed using Scaffold (Proteome Systems, Portland, Oreg.). Protein identifications based upon a single peptide observation were handled carefully through manual inspection of the tandem MS (MS/MS) spectra, BLAST searching of the sequence to ensure it matches only the reported protein, requiring a minimum of 8 amino acids and a peptide probability score of >0.9.

Data analysis flow was based on the following: peptide redundancy removed, protein name redundancy removed, the number of unique peptides and number of observation for each peptide regardless of charge state were determined for each protein and, in the cases where the protein was observed in multiple domains as an indicator of potential PTM this was noted and all data for the protein was included for quantitation.

The number of unique peptides and total number of counts (number of times each peptide is observed) were dependently used to semi-quantify each protein that was observed. To deal with proteins which peptides were only observed at some but not all time points (resulting in no information) a correction factor of 1.25 was used in all R value calculations with a R>0.3 as indicative of change. See 1DLC for more detail.

3. Criteria Selection for 2DLC

-   A) Individual in each group (induced necrosis or induced ischemia)     -   i) Changes in the number of unique peptides or the number of         times each peptide was observed regardless of charge state (+2.         +3 or +4) were compared to the equivalent protein (if observed)         at time point 0. All proteins only seen in time points after         baseline were included.     -   ii) Changes in 3 out of the 3 or 2 out of the 3 individuals in a         designated group (induced ischemia or induced necrosis) at any         time point. -   B) Group     -   i) proteins that met the above criteria for either induced         ischemia or induced necrosis that did not change in all of the         control (non ischemic) samples at any time point.         4. 2DLC Results

Over 7500 spectra were analyzed per pooled sample and thus, over 52,5000 spectra in total. Spectra were removed based on poor quality and each mass was assigned to a single peptide sequence resulting in ˜5500 spectra remaining. The number of the proteins that met the criteria are listed below in table 9. See Example II for detailed protein information.

TABLE 9 protein observed changed by 2DLC IPI increased increased potential present Ische- Ische- present necro- Control accession in in PTM in at base- mia mia at base- sis present at Protein name number Ischemia necrosis any sample line Ti/T0 T2/T0 line T1/T0 baseline Control_T1/T0 Protease, serine, 3 IPI00748381 yes yes no 0 0 > 0 > 0 0 C4b-binding protein IPI00021727 yes yes yes yes 0 > yes > yes = alpha chain Alpha-2-glycoprotein IPI00166729 yes yes yes 0 > > 0 > 0 0 1, zinc (no) Thyroxine-binding IPI00292946 no yes no yes 0 0 0 > 0 0 globulin precursor Criteria was that both number of peptide and number of count must increased increased in ischemia = if protein is increases over baseline in the POOLED sample comprising severe ischemia patients. Ischemia was based on increase in lactate over time and no detectable cTnT increased in necrosis = if protein is increases over baseline in the POOLED sample comprising necrosis patients analyzed. Necrosis was based on detectable cTnT (at time point 2 and or 3) PTM = protein found in multiple fractions in any of the pooled sample. Note, if sequential maybe reflect not PTM but rather large quantity of protein eluting over multiple fractions yes = present at baseline 0 not detected, > greater than baseline < less than baseline = equal to baseline yes - detected at baseline control pool: all T0 = baseline from 13, 19, 9; T1 = time point 1 for 13, 19 and 9 ischemia pool: T0 = baseline from 7, 10, 11; T1 = time point 1 from 7, 10, 11; T2 = time point 2 and 3 from 7, 10, 11 necrosis pool: T0 = baseline and time point 1 for 16,15; T2 = time points 2 and 3 of patient 16 and 15 Interestingly, two proteins, junction plakoglobin, desmoplakin, that are part of the desmonsomal protein complex were detected in a few patients but not enough to make it meet the criteria. Desmoglein-1, the other protein of the same complex was found elevated in necrosis individual with 2DE.

Increase in Increase in Potential Ischemia Ischemia Ischemia name IPI # ischemia necrosis PTM TP1 TP2 TP3 Junction plakoglobin IPI00554711 yes no no 0 > 0 (catenin gamma isoform 1) DPII isoform (most likely IPI00217182 yes no no 0 > 0 also DPI) Desmoplakin (IPI0013933) F. Final Summary of all Protein Changes with Three Methods of Proteomic Analysis

Coronary sinus serum samples were analyzed from patients undergoing atrial pacing. Patients were designated into control, ischemia or necrosis groups based on the presence of cTnT at any time point (necrosis group) and an increase in lactate during the pacing protocol (ischemia and necrosis groups). Depleted samples were analyzed for all patients and all time points by 2DE. Depleted samples for 3 patients that were control, ischemia or necrosis were analyzed at multiple time points by 1DLC. Pooling of these individuals (2 or 3) from control, necrosis and ischemia were required for analyzed by 2DLC due to the amount of protein required for this technology. Proteins selection criteria for each method and MS-based quantitation for each method are described above.

The following proteins have been selected as primary or secondary targets based on the robustness of their changes with ischemia and or necrosis and known biological functions. The overlap is schematically shown in FIG. 5. Detailed information about each target is located in Example II.

Primary Targets

-   Lumican -   Extracellular matrix protein 1 -   Angiogenin -   Semenogelin (all isoforms 1 and 2) -   Long palate, lung and nasal epithelium carcinoma-associated protein     1 (all isoforms, 1 and 2)     Secondary Targets -   Alpha-2-HS-glycoprotein -   Carboxypeptidase N (all subunits including catalytic chain) -   Galectin-7 -   Homerin -   Proteoglycan-4 (Isoform A and D) -   Profilaggrin (Filaggrin) -   Vitamin D binding protein -   C4b-binding protein alpha chain -   Thyroxine binding globulin -   Alpha-2-glycoprotein 1, zinc -   protease, serine 3 -   Caspase 14 -   Desmogelin -   Kininogen-1 (LMW and HMW and bradykinin)

Example II Summary of Some of the Properties of Proteins Discussed with Regard to Cohort I

A. Vitamin D-Binding Protein

-   Name: Vitamin D-binding protein -   IPI ID: IPI00555812 -   UniProtKB/Swiss-Prot entry ID: P02774, Q16309, Q16310 -   Length: 474 aa, molecular weight: 52964 Da (of precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Multifunctional protein found in plasma, ascitic         fluid, cerebrospinal fluid, and urine and on the surface of many         cell types. In plasma, it carries the vitamin D sterols and         prevents polymerization of actin by binding its monomers. DBP         associates with membrane-bound immunoglobulin on the surface of         B-lymphocytes and with IgG Fc receptor on the membranes of         T-lymphocytes.     -   SUBCELLULAR LOCATION: Secreted.     -   POLYMORPHISM: Over 80 variants of human DBP have been         identified. The three most common alleles are called GC*1F,         GC*1S, and GC*2. The sequence shown is that of the GC*2 allele         2. Sequence

(SEQ ID NO: 1) MKRVLVLLLAVAFGHALERGRDYEKNKVCKEFSHLGKEDFTSLSLVLYSRKFPSGTFEQV SQLVKEVVSLTEACCAEGADPDCYDTRTSALSAKSCESNSPFPVHPGTAECCTKEGLERK LCMAALKHQPQEFPTYVEPTNDEICEAFRKDPKEYANQFMWEYSTNYGQAPLSLLVSYTK SYLSMVGSCCTSASPTVCFLKERLQLKHLSLLTTLSNRVCSQYAAYGEKKSRLSNLIKLA QKVPTADLEDVLPLAEDITNILSKCCESASEDCMAKELPEHTVKLCDNLSTKNSKFEDCC QEKTAMDVFVCTYFMPAAQLPELPDVELPTNKDVCDPGNTKVMDKYTFELSRRTHLPEVF LSKVLEPTLKSLGECCDVEDSTTCFNAKGPLLKKELSSFIDKGQELCADYSENTFTEYKK KLAERLKAKLPDATPKELAKLVNKRSDFASNCCSINSPPLYCDSEIDAELKNIL 1-16 leader sequence.

Peptides used in the MS analysis described in this application are indicated by highlighting (shading) in the protein sequences shown herein. A skilled worker can use peptides for some of the proteins which have been described previously by others who have performed MS on those proteins. The sequences of peptides is dependent on the particular type of MS used. For example, the peptides for MALDI can be different from those in ESI. The studies performed herein were ESI.

3. Alternative Names: DBP, Group-specific Component, Gc-Globulin, VDB

4. Additional Information on Function

-   -   Serum vitamin D3-binding protein (Gc protein) is the precursor         for the principal macrophage activating factor (MAF).     -   Gc protein was deglycosylated by serum         alpha-N-acetylgalactosaminidase (Nagalase)     -   The level of Gc globulin is reduced in patients with fulminate         hepatic failure, septic shock and trauma. Furthermore, low         levels of Gc globulin in patients with fulminant hepatic failure         and multiple trauma have been found to correlate with the         morbidity and mortality of patients. It has not been studied in         heart disease.         5. Summary

Assays are available for total Vitamin D binding protein and for the amount of protein which is either free or bound to actin. This protein is known to be diagnostic for several diseases. It seems to be change with cellular injury and decrease with long term chronic disease. Clinical studies and animal models have shown that Gc-globulin has an important role in the clearance of procoagulant actin from the circulation after its release during cell necrosis and tissue injury but it is not known if it is in the heart.

B. Thyroxine-Binding Globulin

-   Name: Thyroxine-binding globulin precursor -   IPI ID: IPI00292946 -   UniProtKB/Swiss-Prot entry ID: P05543 -   Length: 415 aa, molecular weight: 46325 Da (precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Major thyroid hormone transport protein in serum.     -   SUBCELLULAR LOCATION: Secreted.     -   TISSUE SPECIFICITY: Expressed by the liver and secreted in         plasma.     -   DISEASE: Defects in SERPINA7 are a cause of TBG deficiency         [MIM:314200]. Mutations in the SERPINA7 gene can result as a         whole spectrum of deficiencies, characterized by either reduced         or increased TBG levels in the serum. Patients show,         respectively, reduced or elevated protein-bound iodine but are         euthyroid.         2. Sequence

(SEQ ID NO: 2) MSPFLYLVLLVLGLHATIHCASPEGKVTACHSSQPNATLYKMSSINADFAFNLYRRFTVE TPDKNIFFSPVSISAALVMLSFGACCSTQTEIVETLGFNLTDTPMVEIQHGFQHLICSLN FPKKELELQIGNALFIGKHLKPLAKFLNDVKTLYETEVFSTDFSNISAAKQEINSHVEMQ TKGKVVGLIQDLKPNTIMVLVNYIHFKAQWANPFDPSKTEDSSSFLIDKTTTVQVPMMHQ MEQYYHLVDMELNCTVLQMDYSKNALALFVLPKEGQMESVEAAMSSKTLKKWNRLLQKGW VDLFVPKFSISATYDLGATLLKMGIQHAYSENADFSGLTEDNGLKLSNAAHKAVLHIGEK GTEAAAVPEVELSDQPENTFLHPIIQIDRSFMLLILERSTRSILFLGKVVNPTEA 1-20 signal sequence 3. Alternative Names: T4-binding globulin, Serpin A7 4. Summary

Thyroxine-binding globulin binds with high-affinity to the thyroid hormone. It is proposed to be a biomarker for senescence and aging. Chronic treatment with perindopril, an angiotensin I-converting enzyme inhibitor used in cardiac and renal disease, enhanced thyroxine-binding capacity and possibility the protein level itself. In a study on ACS, thyroxine binding globulin was measured in those with acute myocardial infarction after 14 days and there was no change compared to control. It has not been studied in myocardial ischemia or events leding up to MI.

C. Lumican

-   Name: Lumican -   IPI ID: IPI00020986 -   UniProtKB/Swiss-Prot entry ID: -   Length: 338 aa, molecular weight: 38429 Da, (of precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry

SUBUNIT Binds to laminin (By similarity). SUBCELLULAR Secreted, extracellular space, extracellular matrix (By LOCATION similarity). 2. Sequence

(SEQ ID NO: 3) MSLSAFTLFLALIGGTSGQYYDYDFPLSIYGQSSPNCAPECNCPESYPSAMYCDELKLKS VPMVPPGIKYLYLRNNQIDHIDEKAFENVTDLQWLILDHNLLENSKIKGRVFSKLKQLKK LHINHNNLTESVGPLPKSLEDLQLTHNKITKLGSFEGLVNLTFIHLQHNRLKEDAVSAAF KGLKSLEYLDLSFNQIARLPSGLPVSLLTLYLDNNKISNIPDEYFKRFNALQYLRLSHNE LADSGIPGNSFNVSSLVELDLSYNKLKNIPTVNENLENYYLEVNQLEKFDIKSFCKILGP LSYSKIKHLRLDGNRISETSLPPDMYECLRVANEVTLN 1-18 signal sequence 3. Alternative Names:

(Keratan sulfate proteoglycan lumican) (KSPG lumican).

4. Summary

Protein involved in injury response in a number of tissues and is a secreted protein. In a study on the lumican in fibrosis with chronic ischemic and reperfused rat heart. (which is not the acute myocardial infaction model, but rather would induce heart failure), the level of lumican mRNA increased, peaking at the fourth week. The protein level was not investigated. This protein is also known to inhibits cell adhesion and neurite outgrowth and be involved in wound healing of the cornea. It plays an important role in cell migration and proliferation during embryonic development, tissue repair, and tumor growth. It has not been studied in the context of myocardial ischemia or events leading up to MI.

D. Galectin-7

-   Name: Galectin-7 -   IPI ID: IPI00219221 -   UniProtKB/Swiss-Prot entry ID: -   Length: 136 aa, molecular weight: 15075 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry

FUNCTION Could be involved in cell-cell and/or cell-matrix interactions necessary for normal growth control. Pro-apoptotic protein that functions intracellularly upstream of JNK activation and cytochrome c release. SUBCELLULAR Cytoplasm. Nucleus. Secreted (Potential). Note = May LOCATION be secreted by a non-classical secretory pathway. TISSUE Mainly in stratified squamous epithelium. SPECIFICITY 2. Sequence

(SEQ ID NO: 4) MSNVPHKSSLPEGIRPGTVLRIRGLVPPNASRFHVNLLCGEEQGSDAALHFNPRLDTSEV VFNSKEQGSWGREERGPGVPFQRGQPFEVLIIASDDGFKAVVGDAQYHHFRHRLPLARVR LVEVGGDVQLDSVRIF Initial met is removed 3. Alternative Names:

-   Galectin-7 (Gal-7) (HKL-14) (PI7) (p53-induced gene 1 protein). -   Homologous 100% to Q6IB87 HUMAN LGALS7 protein (HCG1776519)     (HCG42850) -   [LGALS7]     Note on Sequence:

Note only 36% homology with galectin 3 which is known to be involved in cancer.

4. Additional Information on Function

The literature suggests that galectin 7 is involved in apoptosis. It is most likely is secreted and forms dimers. Galectin 7 is an emerging marker involved in the epidermal development of pluristratified epithelia and in epidermal cell migration. It is elevated in wound healing. It has not been studied in the context of myocardial ischemia or events leading up to MI.

Extracellular Matrix Protein 1

-   Name: Extracellular matrix protein 1 -   IPI ID: IPI00645849 -   UniProtKB/Swiss-Prot entry ID: Q5T5G4 -   Length: 567 AA (includes signal sequence) -   Molecular weight: 63563 Da (includes signal sequence)     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Not known     -   SUBCELLULAR LOCATION: Secreted, extracellular space.     -   DISEASE: Defects in ECM1 are the cause of lipoid proteinosis         (LiP); also known as lipoid proteinosis of Urbach and Wiethe or         hyalinosis cutis et mucosae. LiP is a rare autosomal recessive         disorder characterized by generalized thickening of skin,         mucosae and certain viscera. Classical features include beaded         eyelid papules and laryngeal infiltration leading to hoarseness.         Histologically, there is widespread deposition of hyaline         material and disruption/reduplication of basement membrane.         2. Sequence Information from 1DLC

(SEQ ID NO: 5) MGTTARAALVLTYLAVASAASEGGFTATGQRQLRPEHFQEVGYAAPPSPPLSRSLPMDHPD SSQHGPPFEGQSGKEGRGPRPHSQPWLGERVGCSHIPPSIVQPPPSQEATPLQQEKLLPAQ LPAEKEVGPPLPQEAVPLQKELPSLQHPNEQKEGTPAPFGDQSHPEPESWNAAQHCQQDRS QGGWGHRLDGFPPGRPSPDNLNQICLPNRQHVVYGPWNLPQSSYSHLTRQGETLNFLEIGY SRCCHCRSHTNRLECAKLVWEEAMSRFCEAEFSVKTRPHWCCTRQGEARFSCFQEEAPQPH YQLRACPSHQPDISSGLELPFPPGVPTLDNIKNICHLRRFRSVPRNLPATDPLQRELLALI QLEREFQRCCRQGNNHTCTWKAWEDTLDKYCDREYAVKTHHHLCCRHPPSPTRDECFARRA PYPNYDRDILTIDIGRVTPNLMGHLCGNQRVLTKHKHIPGLIHNMTARCCDLPFPEQACCA EEEKLTFINDLCGPRRNIWRDPALCCYLSPGDEQVNCFNINYLRNVALVSGDTENAKGQGE QGSTGGTNISSTSEPKEE 3. Alternative Names: Secretory Component P85; Q5T5G5, Q8IZ60, Q5T5G6, Q16610 Note on Sequence:

Signal sequence 1-19 is removed in there mature protein.

4. Summary

Mutations of this protein result in lipoid proteinosis, a rare recessive disorder of the skin and mucosae. It binds perlecan, MMP9 and fibulin in the skin. It can inhibit MMP9. Auto antibodies to this protein occur with lichen sclerosus. Neither disease is common and so specificity to ischemia is likely. It has not been studied in the context of myocardial ischemia or events leading up to MI.

F. Semenogelin 1

-   Name: Semenogelin 1 -   IPI ID: IPI00414684 (Semenogelin-2 precursor IPI00025415) -   UniProtKB/Swiss-Prot entry ID: P04279, Q6X4I9, Q6Y809, Q6Y822,     Q6Y823, Q86U64, Q96QM3 -   Length: 402 aa, molecular weight: 45322 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry

FUNCTION Predominant protein in semen. It participates in the formation of a gel matrix entrapping the accessory gland secretions and ejaculated spermatozoa. Fragments of semenogelin and/or fragments of the related proteins may contribute to the activation of progressive sperm movements as the gel-forming proteins are fragmented by KLK3/PSA. FUNCTION Alpha-inhibin-92 and alpha-inhibin-31, derived from the proteolytic degradation of semenogelin, inhibit the secretion of pituitary follicle-stimulating hormone. SUBUNIT Occurs in disulfide-linked complexes which may also contain two less abundant 71- and 76-kDa semenogelin-related polypeptides. SUBCELLULAR Secreted. LOCATION ALTERNATIVE Event = Alternative splicing; Named isoforms = 2; PRODUCTS Name = 1; IsoId-P04279-1; Sequence = Displayed; Name = 2; IsoId = P04279-2; Sequence = VSP_004385; Note = No experimental confirmation available; TISSUE Seminal vesicle. However references show it is also SPECIFICITY present in other tissues including skeletal muscle 2. Sequence

(SEQ ID NO: 6) MKPNIIFVLSLLLILEKQAAVMGQKGGSKGRLPSEFSQFPHGQKGQHYSGQKGKQQTESK GSFSIQYTYHVDANDHDQSRKSQQYDLNALHKTTKSQRHLGGSQQLLHNKQEGRDHDKSK GHFHRVVIHHKGGKAHRGTQNPSQDQGNSPSGKGISSQYSNTEERLWVHGLSKEQTSVSG AQKGRKQGGSQSSYVLQTEELVANKQQRETKNSHQNKGHYQNVVEVREEHSSKVQTSLCP AHQDKLQHGSKDIFSTQDELLVYNKNQHQTKNLNQDQQHGRKANKISYQSSSTEERRLHY GENGVQKDVSQRSIYSQTEKLVAGKSQIQAPNPKQEPWHGENAKGESGQSTNREQDLLSH EQKGRHQHGSHGGLDIVIIEQEDDSDRHLAQHLNNDRNPLFT 1-23 signal sequence 3. Alternative Names:

SEMG

4. Summary

SGI isoform is found in skeletal muscle as well as epithelial cells. Isoform expression is tissue specific and SGI isoform is found in skeletal muscle as well as epithelial cells. The peptides produced by cleavage of semenogelin I, the predominant human semen coagulum protein, had high levels of antibacterial activity. It has not been studied in the context of myocardial ischemia or events leading up to MI.

G. Isoform 1 of Long Palate, Lung and Nasal Epithelium Carcinoma-Associated Protein 1

-   Name: Isoform 1 of Long palate, lung and nasal epithelium     carcinoma-associated protein 1 -   IPI ID: IPI00291410, -   UniProtKB/Swiss-Prot entry ID: Q8TDL5-1 -   Length: 484 aa, molecular weight: 52442 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry

FUNCTION May play a role in innate immunity in mouth, nose and lungs. SUBCELLULAR Secreted (By similarity). LOCATION ALTERNATIVE Event = Alternative splicing; Named isoforms = 2; PRODUCTS Name = 1; IsoId = Q8TDL5-1; Sequence = Displayed; Name = 2; IsoId = Q8TDL5-2; Sequence = VSP_015285, VSP_015286, VSP_015287, VSP_015288; Note = No experimental confirmation available; TISSUE Detected in trachea, nasal septal epithelium and lung. SPECIFICITY 0 hits 2. Sequence

(SEQ ID NO: 7) MAGPWTFTLLCGLLAATLIQATLSPTAVLILGPKVIKEKLTQELKDENATSILQQLPLLS AMREKPAGGIPVLGSLVNTVLKHIIWLKVITANILQLQVKPSANDQELLVKIPLDMVAGF NTPLVKTIVEFHMTTEAQATIRMDTSASGPTELVLSDCATSHGSLRIQLLHKLSFLVNAL AKQVMNLLVPSLPNLVKNQLCPVIEASFNGMYADLLQLVKVPISLSIDRLEFDLLYPAIK GDTIQLYLGAKLLDSQGKVTKWFNNSAASLTMPTLDNIPFSLIVSQDVVKAAVAAVLSPE EFMVLLDSVLPESAHRLKSSIGLINEKAADKLOSTQIVKILTQDTPEFFIDQGHAKVAQL IVLEVFPSSEALRPLFTLGIEASSEAQFYTKODQLILNINNISSDRIQLMNSGIGWFQPD VLKNIITEIIHSILLPNQNGKLRSGVPVSLVKALGFEAAESSLTKDALVLTPASLWKPSS PVSQ 1-21 potential signal sequence. Isoform 2 is truncated at N-terminus. Also have insert (underlined) which has no peptides. Therefore, cannot distinguish between isoform one and two 3. Alternative Names: C20orf114 4. Summary

Little is known about this protein or its shorter isoform (2). It has not been studied in the context of myocardial ischemia or events leading up to MI.

H. Angiogenin

-   Name: Angiogenin, precursor -   IPI ID: IPI00008554 -   UniProtKB/Swiss-Prot entry ID: P03950 -   Length: 147 AA [This is the length of the unprocessed precursor] -   Molecular weight: 42051 Da [This is the MW of the unprocessed     precursor     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: May function as a tRNA-specific ribonuclease that         binds to actin on the surface of endothelial cells; once bound,         angiogenin is endocytosed and translocated to the nucleus,         thereby promoting the endothelial invasiveness necessary for         blood vessel formation. Angiogenin induces vascularization of         normal and malignant tissues. Abolishes protein synthesis by         specifically hydrolyzing cellular tRNAs.     -   INTERACTIONS: May bind alpha-actinin P35609     -   SUBCELLULAR LOCATION: Secreted     -   TISSUE SPECIFICITY: Expressed predominantly in the liver.     -   DEVELOPMENTAL STAGE: Low level expression in the developing         fetus, increased in the neonate, and maximal in the adult     -   SIMILARITY: Belongs to the pancreatic ribonuclease family.         -   It is uncertain whether Met-1 or Met-3 is the initiator.             2. Sequence Information from 1DLC

(SEQ ID NO: 8) MVMGLGVLLL VFVLGLGLTP PTLAQDNSRY THFLTQHYDA KPQGRDDRYC ESIMRRRGLT SPCKDINTFI HGNKRSIKAI CENKNGNPHR ENLRISKSSF QVTTCKLHGG SPWPPCQYRA TAGFRNVVVA CENGLPVHLD QSIFRRP Multiple Peptides 3. Alternative names: RNASE5, Ribonuclease A Family, 5, RNASE4 Protein, ANG Protein Q53X86, Q6P5T2

Note on Sequence:

-   -   Most likely have either intact molecule or the mature processed         form.     -   Signal peptide residues 1-24

Additional information on function Angiogenin is a normal constituent of the circulation and contained in a vasculature that rarely undergoes proliferation, but in some physiological and pathological conditions its levels increase in blood, promoting neovascularization. This is a potentially important physiological protein involved in angiogenesis.

4. Summary

Interestingly, this protein may play a role in angiogenesis. Recently it has been potentially linked to poor outcome in ACS patients, which is a chronic condition that can result from many different etiologies. Plasma angiogenin levels was increased in ACS also with ischemic brain damage. However, it has not been studied in the context of myocardial ischemia or events leading up to MI.

1. C4b-Binding Protein

-   Name: C4b-binding protein (alpha chain)r -   IPI ID: IPI00021727 -   UniProtKB/Swiss-Prot entry ID: P04003 -   Length: 597 AA [This is the length of the unprocessed precursor] -   Molecular weight: 67033 Da [This is the MW of the unprocessed     precursor]     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Controls the classical pathway of complement         activation. It binds as a cofactor to C3b/C4b inactivator         (C3bINA), which then hydrolyzes the complement fragment C4b. It         also accelerates the degradation of the C4bC2a complex (C3         convertase) by dissociating the complement fragment C2a. Alpha         chain binds C4b. It interacts also with anticoagulant protein S         and with serum amyloid P component.     -   SUBUNIT: Disulfide-linked complex of alpha and beta chains of 3         possible sorts: a 570 kDa complex of 7 alpha chains and 1 beta         chain, a 530 kDa homoheptamer of alpha chains or a 500 kDa         complex of 6 alpha chains and 1 beta chain. The central body of         the alpha chain homopolymer supports tentacles, each with the         binding site for C4b at the end.     -   SUBCELLULAR LOCATION: Secreted     -   TISSUE SPECIFICITY: Chylomicrons in the plasma.     -   It is uncertain whether Met-1 or Met-17 is the initiator         Additional Information     -   CRP binds C4b binding proteins and regulations it inhibition of         complement system (Regulation of Complement Activation by         C-Reactive Protein: Targeting of the Inhibitory Activity of         C4b-Binding Protein¹ AP Sjöberg et al., J. Immuno. 2006, 176:         7612-7620).     -   C4b-binding protein (C4BP), binds strongly to necrotic cells,         irrespective of the cell type used or the method of induction.         (C4b-binding protein binds to necrotic cells and DNA, limiting         DNA release and inhibiting complement activation L A. Trouw et         al., JEM, 2005, 201, 1937-1948)         2. Sequence

(SEQ ID NO:9)

NGQVEIKTDL SFGSQIEFSC SEGFFLIGST TSRCEVQDRG VGWSHPLPQC EIVKCKPPPD IRNGRHSGEE NFYAYGFSVT YSCDPRFSLL GHASISCTVE NETIGVWRPS PPTCEKITCR

Green both 1DLC and 2DLC Blue only 2DLC 3. Alternative Names: IC4b Binding Protein, C4b Binding Protein Alpha Chain, C4b Receptor, C4bP, C4bPA, C4bPAL1, Complement Component 4 Binding Protein, Alpha like 1, PRP, Proline Rich Protein Complement Component 4 Binding Protein, Alpha. Q5VVQ8

Note on Sequence:

Most likely intact protein. Several patients had protein present in multiple fractions and although sequential appears to be due to PTM rather than bleed over between two fractions. E do not know what the PTM is at this time. This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

J. Carboxypeptidase N Catalytic Chain

-   Name: Carboxypeptidase N catalytic chain precursor -   IPI ID: IPI00021439 -   UniProtKB/Swiss-Prot entry ID: P15169 -   Length: 458 AA [This is the length of the unprocessed precursor] -   Molecular weight: 52286 Da [This is the MW of the unprocessed     precursor]     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Protects the body from potent vasoactive and         inflammatory peptides containing C-terminal Arg or Lys (such as         kinins or anaphylatoxins) which are released into the         circulation. Note cleaves bradykinin!     -   CATALYTIC ACTIVITY: Release of a C-terminal basic amino acid,         preferentially lysine.     -   SUBUNIT: Tetramer of two catalytic chains and two glycosylated         inactive chains.     -   SUBCELLULAR LOCATION: Secreted/extracellular space     -   SIMILARITY: Belongs to the peptide M14 family         2. Sequence

(SEQ ID NO: 10) MSDLLSVFLH LLLLFKLVAP VTFRHHRYDD LVRTLYKVQN ECPGITRVYS IGRSVEGRHL YVLEFSDHPG IHEPLEPEVK YVGNMHGNEA LGRELMLQLS EFLCEEFRNR NQRIVQLIQD TRIHILPSMN PDGYEVAAAQ GPNKPGYLVG RNNANGVDLN RNFPDLNTYI YYNEKYGGPN HHLPLPDNWK SQVEPETRAV IRWMHSFNFV LSANLHGGAV VANYPYDKSF EHRVRGVRRT ASTPTPDDKL FQKLAKVYSY AHGWMFQGWN CGDYFPDGIT NGASWYSLSK GMQDFNYLHT NCFEITLELS CDKFPPEEEL QREWLGNREA LIQFLEQVHQ GIKGMVLDEN YNNLANAVIS VSGINHDVTS GDHGDYFRLL LPGIYTVSAT APGYDPETVT VTVGPAEPTL VNFHLKRSIP QVSPVRRAPS RRHGVRAKVQ PQARKKEMEM RQLQRGPA 3. Alternative Names: CPN, Carboxypeptidase N polypeptide 1, Carboxypeptidase N Small Subunit; Lysine carboxypeptidase, Arginine carboxypeptidase, Kininase-1, Serum carboxypeptidase NSCPN, Anaphylatoxin inactivator, Plasma carboxypeptidase B Q5T287

Note on sequence: Signal sequence 1-20

4. Summary

Interesting protein, which may alter bradykinin levels and creatine kinase levels. Involved in early inflammatory response. Has been shown to be elevated after AMI based on activity assays. Although it has been shown that there is a high degree of variability in carboxypeptidase N in healthy subjects and does not change with acute myocardial infarction patients but may reach maximum at 48 h after onset of chest pain. It has not been studied in the context of myocardial ischemia or events leading up to MI.

K. Profilaggrin/Filaggrin

-   Name: Profilaggrin (Filaggrin) -   IPI ID: IPI00746718 -   UniProtKB/Swiss-Prot entry ID: P20930 (note only 70% homology) -   Length: 4061AA -   Molecular weight: 435170 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Aggregates keratin intermediate filaments and promotes         disulfide-bond formation among the intermediate filaments during         terminal differentiation of mammalian epidermis     -   PTM: Filaggrin is initially synthesized as a large, insoluble,         highly phosphorylated precursor containing many tandem copies of         324 AA, which are not separated by “large linker”. The precursor         is deposited as keratohyalin granules. During terminal         differentiation it is dephosphorylated and proteolytically         cleaved.     -   PTM: Undergoes deimination of some arginine residues         (citrullination).     -   DISEASE: Defects in FLG are the cause of ichthyosis vulgaris         [MIM:146700]; also known as ichthyosis simplex. The phenotypic         characteristics of ichthyosis vulgaris include palmar,         hyperlinearity, keratosis pilaris and a fine scale that is most         prominent over the lower abdomen, arms, and legs. Ichthyosis         vulgaris is characterized histologically by absent or reduced         keratohyalin granules in the epidermis and mild hyperkeratosis.         The disease can be associated with frequent asthma, eczema or         hay fever. Inheritance is autosomal dominant.         2. Sequence (IPI Sequence)

(SEQ ID NO: 11) MSTLLENIFAIINLFKQYSKKDKNTDTLSKKELKELLEKEFRQILKNPDDPDMVDVFMDH LDIDHNKKIDFTEFLLMVFKLAQAYYESTRKENLPISGHKHRKHSHHDKHEDNKQEENKE NRKRPSSLERRNNRKGNKGRSKSPRETGGKRHESSSEKKERKGYSPTHREEEYGKNHHNS SKKEKNKTENTRLGDNRKRLSERLEEKEDNEEGVYDYENTGRMTQKWIQSGHIATYYTIQ DEAYDTTDSLLEENKIYERSRSSDGKSSSQVNRSRHENTSQVPLQESRTRKRRGSRVSQD RDSEGHSEDSERHSGSASRNHHGSAWEQSRDGSRHPRSHDEDRASHGHSADSSRQSGTRH AETSSRGQTASSHEQARSSPGERHGSGHQQSADSSRHSATGRGQASSAVSDRGHRGSSGS QASDSEGHSENSDTQSVSGHGKAGLRQQSHQESTRGRSGERSGRSGSFIYQVSTHEQSES AHGRTRTSTGRRQGSHHEQARDSSRHSASQEGQDTIRAHPGSRRGGRQGSHHEQSVDRSG HSGSHHSHTTSQGRSDVSRGQSGSRSVSRQTRNEKQSGDGSRHSGSRHHEASSRADSSRH SQVGQGQSSGPRTSRNQGSSVSQDSDSQGHSEDSERRSGSASRNHHGSAQEQSRDGSRHP RSHHEDRAGHGHSAESSRQSGTHHAENSSGGQAASSHEQARSSAGERHGSHHQQSADSSR HSGIGHGQASSAVRDSGHRGSSGSQASDSEGHSEDSDTQSVSAHGQAGPHQQSHQESTRG RSAGRSGRSGSFLYQVSTHEQSESAHGRTRTSTGRRQGSHHEQARDSSRHSASQEGQDTI RGHPGSSRRGRQGSHYEQSVDRSGHSGSHHSHTTSQGRSDASRGQSGSRSASRQTRNDEQ SGDGSRHSWSHHHEASTQADSSRHSQSGQGQSAGPRTSRNQGSSVSQDSDSQGHSEDSER WSGSASRNHRGSAQEQSRDGSRHPTSHHEDRAGHGHSAESSRQSGTHHAENSSGGQAASS HEQARSSAGERHGSHHQQSADSSRHSGIGHGQASSAVRDSGHRGSSGSQASDSEGHSEDS DTQSVSAHGQAGPHQQSHQESTRGRSAGRSGRSGSFLYQVSTHEQSESAHGRAGPSTGGR QGSRHEQARDSSRHSASQEGQDTIRGHPGSRRGGRQGSYHEQSVDRSGHSGSHESHTTSQ GRSDASHGQSGS 3. Summary

Peptides observed are unique to Filaggrin (and not to Ifapsoriasin or Hornerin). This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

L. Proteoglycan-4

-   Name: Isoform A and D of Proteoglycan-4 (we cannot distinguish     isoforms due to high degree of sequence homology) -   IPI ID: IPI00024825 and IPI00655676 -   UniProtKB/Swiss-Prot entry ID: Q92954, Q6DNC4, Q6DNC5, Q6ZMZ5,     Q9BX49 -   Length: 1404 aa, molecular weight: 151077 Da     1. Sequence

(SEQ ID NO: 12) MAWKTLPIYLLLLLSVFVIQQVSSQDLSSCAGRCGEGYSRDATCNCDYNCQHYMECCPDF KRVCTAELSCKGRCFESFERGRECDCDAQCKKYDKCCPDYESFCAEVHNPTSPPSSKKAP PPSGASQTIKSTTKRSPKPPNKKKTKKVIESEEITEEHSVSENQESSSSSSSSSSSSTIR KIKSSKNSAANRELQKKLKVKDNKKNRTKKKPTPKPPVVDEAGSGLDNGDFKVTTPDTST TQHNKVSTSPKITTAKPINPRPSLPPNSDTSKETSLTVNKETTVETKETTTTNKQTSTDG KEKTTSAKETQSIEKTSAKDLAPTSKVLAKPTPKAETTTKGPALTTPKEPTPTTPKEPAS TTPKEPTPTTIKSAPTTPKEPAPTTTKSAPTTPKEPAPTTTKEPAPTTPKEPAPTTTKEP APTTTKSAPTTPKEPAPTTPKKPAPTTPKEPAPTTPKEPTPTTPKEPAPTTKEPAPTTPK EPAPTAPKKPAPTTPKEPAPTTPKEPAPTTTKEPSPTTPKEPAPTTTKSAPTTTKEPAPT TTKSAPTTPKEPSPTTTKEPAPTTPKEPAPTTPKKPAPTTPKEPAPTTPKEPAPTTTKKP APTTPKEPAPTTPKETAPTTPKKLTPTTPEKLAPTTPEKPAPTTPEELAPTTPEEPTPTT PEEPAPTTPKAAAPNTPKEPAPTTPKEPAPTTPKEPAPTTPKETAPTTPKGTAPTTLKEP APTTPKKPAPKELAPTTTKEPTSTTCDKPAPTTPKGTAPTTPKEPAPTTPKEPAPTTPKG TAPTTLKEPAPTTPKKPAPKELAPTTTKGPTSTTSDKPAPTTPKETAPTTPKEPAPTTPK KPAPTTPETPPPTTSEVSTPTTTKEPTTIHKSPDESTPELSAEPTPKALENSPKEPGVPT TKTPAATKPEMTTTAKDKTTERDLRTTPETTTAAPKMTKETATTTEKTTESKITATTTQV TSTTTQDTTPFKITTLKTTTLAPKVTTTKKTITTTEIMNKPEETAKPKDRATNSKATTPK PQKPTKAPKKPTSTKKPKTMPRVRKPKTTPTPRKMTSTMPELNPTSRIAEAMLQTTTRPN QTPNSKLVEVNPKSEDAGGAEGETPHMLLRPHVFMPEVTPDMDYLPRVPNQGIIINPMLS DETNICNGKPVDGLTTLRNGTLVAFRGHYFWMLSPFSPPSPARRITEVWGIPSPIDTVFT RCNCEGKTFFFKDSQYWRFTNDIKDAGYPKPIFKGFGGLTGQIVAALSTAKYKNWPESVY FFKRGGSIQQYIYKQEPVQKCPGRRPALNYPVYGETTQVRRRRFERAIGPSQTHTIRIQY SPARLAYQDKGVLHNEVKVSILWRGLPNVVTSAISLPNIRKPDGYDVIAFSKDQYYNIDV PSRTARAITTRSGQTLSKVWYNCP

1 24 24 Potential. signal 25 1404 1380 Proteoglycan-4. 1307 1404 98 Proteoglycan-4 C-terminal part.. 26 66 41 Missing (in isoform B, isoform D and isoform E). 107 199 93 Missing (in isoform C and isoform D). 157 199 43 Missing (in isoform F). 412 841 430 Missing (in isoform E). 2. Alternative names: Proteoglycan-4 Precursor (Lubricin) (Megakaryocyte-Stimulating Factor) (Superficial Zone Proteoglycan) [Contains: Proteoglycan-4 C-terminal part]. 3. Summary

PRG4 (proteoglycan 4) is a megakaryocyte stimulating factor and articular superficial zone protein which is expressed in cartilage, liver, heart, lung, and bone. It is known to be involved in the lubrication of mammalian joints. This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

M. Alpha-2-HS-Glycoprotein

-   Name: Alpha-2-HS-glycoprotein -   IPI ID: IPI00022431 -   UniProtKB/Swiss-Prot entry ID: P02765 -   Length: 367 aa, molecular weight: 39325 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry

FUNCTION Promotes endocytosis, possesses opsonic properties and influences the mineral phase of bone. Shows affinity for calcium and barium ions. SUBUNIT Alpha-2-HS glycoprotein derives from this precursor, when the connecting peptide is cleaved off. The two chains A and B are held together by a single disulfide bond. SUBCELLULAR Secreted. LOCATION TISSUE Synthesized in liver and selectively concentrated in SPECIFICITY bone matrix. Secrete din plasma. It is also found in dentin in much higher quantities than other plasma proteins. 2. Sequence

(SEQ ID NO: 13) MKSLVLLLCLAQLWGCHSAPHGPGLIYRQPNCDDPETEEAALVAIDYINQNLPWGYKHTL NQIDEVKVWPQQPSGELFEIEIDTLETTCHVLDPTPVARCSVRQLKEHAVEGDCDFQLLK LDGKFSVVYAKCDSSPDSAEDVRKVCQDCPLLAPLNDTRVVHAAKAALAAFNAQNNGSNF QLEEISRAQLVPLPPSTYVEFTVSGTDCVAKEATEAAKCNLLAEKQYGFCKATLSEKLGG AEVAVTCTVFQTQPVTSQPQPEGANEAVPTPVVDETAITSFTLGAPGLITAGSETDSHVL LAAPPGHQLHRAHYDLRHTFMGVVSLGSPSGEVSHPRKTRTVVQPSVGAAAGPVVPPCPG RIRHFKV 1-18 Signal Sequence 3. Alternative Names:

Alpha-2-HS-glycoprotein precursor (Fetuin-A) (Alpha-2-Z-globulin) (Ba-alpha-2-glycoprotein) [Contains: Alpha-2-HS-glycoprotein chain A; Alpha-2-HS-glycoprotein chain B].

4. Summary Very high abundant protein and found to change in many diseases and acts as a calcification inhibitor. It inhibits inflammation. It is elevated late after acute myocardial infarction but did not correlate with peak cardiac troponin values. This protein has not been studied in the context of myocardial ischemia or events leading up to MI. N. Protease, Serine, 3 (Mesotrypsinogen) IPI00748381

-   Name: Protease, serine, 3 -   IPI ID: IPI00748381 -   UniProtKB/Swiss-Prot entry ID: Q5JT15 -   Length: 249AA [This is the length of the unprocessed precursor] -   Molecular weight: 26914 Da [This is the MW of the unprocessed     precursor     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION (mesotrypsinogen data): Preferential cleavage:         Arg-|-Xaa, Lys-|-Xaa. Cofactor Binds 1 calcium ion per subunit.     -   INTERACTIONS: This protein binds to Amyloid beta A4 (which we         observe but do not see changed) and tissue factor pathway         inhibitor (see HPRD)     -   SUBCELLULAR LOCATION: Secreted.     -   TISSUE SPECIFICITY: Pancreas and brain.         2. Sequence Information from 2DLC

Note: this protein was identified in different fractions for ischemia vs AMI. This suggests that this protein has undergone a PTM with AMI and thus is physically distinct from the form present during ischemia. We do not know what this PTM(s) is at this time.

Sequence

(SEQ ID NO: 14) MNPFLILAFVGAAGEVAVPFDDDDKIVGGYTCEENSLPYQVSLNSGSHFCGGSLISEQWV VSAAHCYKTRIQVRLGEHNIKVLEGNEQFINAAKIIRHPKYNRD TLDNDIMLIK LSSPAV INARVSTISLPTTPPAAGTECLISGWGNTLSFGADYPDELKCLDAPVLTQAECKASYPGK ITNSMFCVGFLEGGKDSCQRDSGGPVVCNGQLQGVVSWGHGCAWK NRPGVYTK VYNYVDW IKDTIAANS bold amino acids are trypsin-like domain 3. Alternative Names:

Uncharacterized protein PRSS3 A6NN76, Mesotrypsin C Q6ISJ4, Mesotrypsinogen C P35030-3 (98% homologous and not in region of the observed peptides), Isoform C of P35030 P35030-3, Isoform B of P35030 P35030-2. Based on HPRD this is the same protein as trypsinogen IV (has same sequence), protease serine, 4, TRY3, TRY4, trypsin 3, trypsin 4 (Brain), trypsinogen III (pancreatic).

Note: In swiss prot, mesotrysinogen has three isoforms—two of which are longer proteins at the N-terminus. We can not distinguish between the three isoforms.

Note on sequence:

We cannot distinguish between the three highly conserved isoforms of mesotrypsinogen based on MS data.

4. Summary

Mesotrypsin is an inhibitor-resistant protease and is secreted from pancreatic juice. Whether it is present in the heart is not known. This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

O. Alpha-2-glycoprotein 1, zinc IPI00166729

-   Name: alpha-2-glycoprotein 1, zinc -   IPI ID: IPI00166729 -   UniProtKB/Swiss-Prot entry ID: Q8N4N0 Q5XKQ4 -   Length: 298 AA [This is the length of the unprocessed precursor] -   Molecular weight: 34259 Da [This is the MW of the unprocessed     precursor     1. Basic Information from UniProtKB/Swiss-Prot Entry     -   FUNCTION: Stimulates lipid degradation in adipocytes and causes         the extensive fat losses associated with some advanced cancers.         May bind polyunsaturated fatty acids.     -   SUBCELLULAR LOCATION: Secreted.     -   TISSUE SPECIFICITY: Blood plasma, seminal plasma, urine, saliva,         sweat, epithelial cells of various human glands, liver.         2. Sequence

(SEQ ID NO: 15) MVRMVPVLLSLLLLLGPAVPQENQDGRYSLTYIYTGLSKHVEDVPAFQAL GSLNDLQFFRYNSKDRKSQPMGLWRQVEGMEDWKQDSQLQKAREDIFMET LKDIVEYYNDSNGSHVLQGRFGCEIENNRSSGAFWKYYYDGKDYIEFNKE IPAWVPFDPAAQITKQKWEAEPVYVQRAKAYLEEECPATLRKYLKYSKNI LDRQDPPSVVVTSHQAPGEKKKLKCLAYDFYPGKIDVHWTRAGEVQEPEL RGDVLHNGNGTYQSWVVVAVPPQDTAPYSCHVQHSSLAQPLVVPWEAS

Note on sequence: note initiating Met is cleaved. There maybe a PTM with ischemia as the peptides elute at different fractions at T-1 and T-2. We do not know what the PTM is.

3. Alternative Names: Alpha-2-glycoprotein 1 Q5XKQ4, zinc binding; zinc-alpha-2-glycoprotein P25311 (295 AA and 33872 Da, over 95% homology)

4. Summary Zinc-alpha2-glycoprotein (ZAG) is a a lipid mobilizing factor found in adipose tissue. It is increased in a number of cancers. Nothing is known about with respect to the heart and myocardial ischemia. It has not been studied in the context of myocardial ischemia or events leading up to MI. P. Desmoglein-1

-   Name: Desmoglein-1 -   IPI ID: I PI00025753 -   UniProtKB/Swiss-Prot: Q02413 -   Length: 1049 AA [This is the length of the unprocessed precursor] -   Molecular Weight: 113716 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry Q02413     -   FUNCTION: Component of intercellular desmosome junctions.         Involved in the interaction of plaque proteins and intermediate         filaments mediating cell-cell adhesion.     -   SUBCELLULAR LOCATION: Cell membrane; Single-pass type I membrane         protein (By similarity).     -   SIMILARITY: Contains 4 cadherin domains     -   TISSUE SPECIFICITY: Epidermis, tongue, tonsil and esophagus.     -   DISEASE: Defects in DSG1 are the cause of keratosis         palmoplantaris striata I (PPKS1) [MIM: 148700]; also known as         striate palmoplantar keratoderma I (SPPK1). PPKS1 is an         autosomal dominant disease characterized by thickening of the         skin on the palms and soles, and longitudinal hyperkeratotic         lesions on the palms, running the length of each finger.         Protein ID Data -   SEPARATION METHOD: 2DE -   EXPECTED MOLECULAR WEIGHT/PI: 113716 Da/4.90 -   OBSERVED MOLECULAR WEIGHT/PI: 59 KD/5.8 -   NOTE: It could be processed the product.     2. Sequence

(SEQ ID NO: 16) MDWSFFRVVAVLFIFLVVVEVNSEFRIQVRDYNTKNGTIKWHSIRRQKRE WIKFAAACREGEDNSKRNPIAKIHSDCAANQQVTYRISGVGIDQPPYGIF VINQKTGEINITSIVDREVTPFFIIYCRALNSMGQDLERPLELRVRVLDI NDNPPVFSMATFAGQIEENSNANTLVMILNATDADEPNNLNSKIAFKIIR QEPSDSPMFIINRNTGEIRTMNNFLDREQYGQYALAVRGSDRDGGADGMS AECECNIKILDVNDNIPYMEQSSYTIEIQENTLNSNLLEIRVIDLDEEFS ANWMAVIFFISGNEGNWFEIEMNERTNVGILKVVKPLDYEAMQSLQLSIG VRNKAEFHHSIMSQYKLKASAISVTVLNVIEGPVFRPGSKTYVVTGNMGS NDKVGDFVATDLDTGRPSTTVRYVMGNNPADLLAVDSRTGKLTLKNKVTK EQYNMLGGKYQGTILSIDDNLQRTCTGTININIQSFGNDDRTNTEPNTKI TTNTGRQESTSSTNYDTSTTSTDSSQVYSSEPGNGAKDLLSDNVHFGPAG IGLLIMGFLVLGLVPFLMICCDCGGAPRSAAGFEPVPECSDGAIHSWAVE GPQPEPRDITTVIPQIPPDNANIIECIDNSGVYTNEYGGREMQDLGGGER MTGFELTEGVKTSGMPEICQEYSGTLRRNSMRECREGGLNMNFMESYFCQ KAYAYADEDEGRPSNDCLLIYDIEGVGSPAGSVGCCFIGEDLDDSFLDTL GPKFKKLADISLGKESYPDLDPSWPPQSTEPVCLPQETEPVVSGHPPISP HFGTTTVISESTYPSGPGVLHPKPILDPLGYGNVTVTESYTTSDTLKPSV HVHDNRPASNVVVTERVVGPISGADLHGMLEMPDLRDGSNVIVTERVIAP SSSLPTSLTIHHPRESSNVVVTERVIQPTSGMIGSLSMHPELANAHNVIV TERVVSGAGVTGISGTTGISGGIGSSGLVGTSMGAGSGALSGAGISGGGI GLSSLGGTASIGHMRSSSDHHFNQTIGSASPSTARSRITKYSTVQYSK 3. Summary This protein is part of the desmosome cell junctions in many cell types including the heart. The protein is the antigen for Pemphigus foliaceus is an autoimmune skin disease. It binds to plakophilin 1, plakophilin 2, desmoplakin, desmoglein 1, desmoglein 4, plakoglobin and corneodesmosin, all of which maybe potential biomarkers in myocardial ischemia. It has not been studied in the context of myocardial ischemia or events leading up to MI. Q. Caspase-14

-   Name: Caspase-14 -   IPI ID: IPI00013885 -   UniProtKB/Swiss-Prot: P31944 -   Length: 242 AA [this is the length of the unprocessed precursor]     -   propeptide=1-? AA     -   sub-unit 1=?-146 AA,     -   sub-unit 2=147-242 AA -   Molecular Weight: 27680 Da [this is the MW of the unprocessed     precursor]     1. Basic Information from UniProtKB/Swiss-Prot Entry P31944     -   FUNCTION: May be involved in the death receptor and granzyme B         apoptotic pathways. May function as a downstream signal         transducer of cell death.     -   SUBUNIT: May dimerize with large prodomain caspases.     -   SUBCELLULAR LOCATION: Cytoplasm (By similarity).         Protein ID Data -   Separation method: 2DE -   Expected molecular weight/pI: 27680 Da/5.44 (pro-caspase-14=242 AA) -   Observed molecular weight/pI: 68000 Da/6.8, -   Note: There is difference in observed and expected MW, multiple     proteins complex?     2. Sequence

(SEQ ID NO: 17) MSNPRSLEEE KYDMSGARLA LILCVTKARE GSEEDLDALE HMFRQLRFES TMKRDPTAEQ FQEELEKFQQ AIDSREDPVS CAFVVLMAHG REGFLKGEDG EMVKLENLFE ALNNKNCQAL RAKPKVYIIQ ACRGEQRDPG ETVGGDEIVM VIKDSPQTIP TYTDALHVYS TVEGYIAYRH DQKGSCFIQT LVDVFTKRKG HILELLTEVT RRMAEAELVQ EGKARKTNPE IQSTLRKRLY LQ 3. Summary

Casp14 may play a role in ontogenesis and skin physiology. CASP14 cDNA and determined that CASP14 contains 7 exons encoding a 242-amino acid protein, 2 CASP14 transcripts (CASP14a and CASP14b) differ in the C terminus while an alternative splice acceptor site within intron 5 results in a 74-nucleotide insertion in CASP14b. CASP14b lacks homology with the caspase consensus sequence. CASP14 has been found in epidermis, hair follicles, the sebaceous gland. NO treatment of neonatal mouse cardiomyocytes in culture causes increase in caspase 14. There is also increase in this protein in canine brain during cardiac arrest and resuscitation. This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

R. Hornerin

-   Name: HORNERIN -   IPI ID: IPI00398625 -   UniProtKB/Swiss-Prot ID: Q86YZ3 -   Length: 2850 aa, molecular weight: 282390 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION May play a role in cornification. SUBCELLULAR Cytoplasmic granule (By similarity). Note = Found LOCATION in keratohyalin granules in the granular cells of the epidermis (By similarity). 2. Sequence:

(SEQ ID NO: 18) MPKLLQGVITVIDVFYQYATQHGEYDTLNKAELKELLENEFHQILKNPND PDTVDIILQSLDRDHNKKVDFTEYLLMIFKLVQARNKIIGKDYCQVSGSK LRDDTHQHQEEQEETEKEENKRQESSFSHSSWSAGENDSYSRNVRGSLKP GTESISRRLSFQRDFSGQHNSYSGQSSSYGEQNSDSHQSSGRGQCGSGSG QSPNYGQHGSGSGQSSSNDTHGSGSGQSSGFSQHKSSSGQSSGYSQHGSG SGHSSGYGQHGSRSGQSSRGERHRSSSGSSSSYGQHGSGSRQSLGHGRQG SGSRQSPSHVRHGSGSGHSSSHGQHGSGSSYSYSRGHYESGSGQTSGFGQ HESGSGQSSGYSKHGSGSGHSSSQGQHGSTSGQASSSGQHGSSSRQSSSY GQHESASRHSSGRGQHSSGSGQSPGHGQRGSGSGQSPSSGQHGTGFGRSS SSGPYVSGSGYSSGFGHHESSSEHSSGYTQHGSGSGHSSGHGQHGSRSGQ SSRGERQGSSAGSSSSYGQHGSGSRQSLGHSRHGSGSGQSPSPSRGRHES GSRQSSSYGPHGYGSGRSSSRGPYESGSGHSSGLGHQESRSGQSSGYGQH GSSSGHSSTHGQHGSTSGQSSSCGQHGATSGQSSSHGQHGSGSSQSSRYG QQGSGSGQSPSRGRHGSDFGHSSSYGQHGSGSGWSSSNGPHGSVSGQSSG FGHKSGSGQSSGYSQHGSGSSHSSGYRKHGSRSGQSSRSEQHGSSSGLSS SYGQHGSGSHQSSGHGRQGSGSGHSPSRVRHGSSSGHSSSHGQHGSGTSC SSSCGHYESGSGQASGFGQHESGSGQGYSQHGSASGHFSSQGRHGSTSGQ SSSSGQHDSSSGQSSSYGQHESASHHASGRGRHGSGSGQSPGHGQRGSGS GQSPSYGRHGSGSGRSSSSGRHGSGSGQSSGFGHKSSSGQSSGYTQHGSG SGHSSSYEQHGSRSGQSSRSEQHGSSSGSSSSYGQHGSGSRQSLGHGQHG SGSGQSPSPSRGRHGSGSGQSSSYGPYRSGSGWSSSRGPYESGSGHSSGL GHRESRSGQSSGYGQHGSSSGHSSTHGQHGSTSGQSSSCGQHGASSGQSS SHGQHGSGSSQSSGYGRQGSGSGQSPGHGQRGSGSRQSPSYGRHGSGSGR SSSSGQHGSGLGESSGFGHHESSSGQSSSYSQHGSGSGHSSGYGQHGSRS GQSSRGERHGSSSGSSSHYGQHGSGSRQSSGHGRQGSGSGHSPSRGRHGS GLGHSSSHGQHGSGSGRSSSRGPYESRSGHSSVFGQHESGSGHSSAYSQH GSGSGHFCSQGQHGSTSGQSSTFDQEGSSTGQSSSYGHRGSGSSQSSGYG RHGAGSGQSPSRGRHGSGSGHSSSYGQHGSGSGWSSSSGRHGSGSGQSSG FGHHESSSWQSSGCTQHGSGSGHSSSYEQHGSRSGQSSRGERHGSSSGSS SSYGQHGSGSRQSLGHGQHGSGSGQSPSPSRGRHGSGSGQSSSYSPYGSG SGWSSSRGPYESGSSHSSGLGHRESRSGQSSGYGQHGSSSGHSSTHGQHG STSGQSSSCGQHGASSGQSSSHGQHGSGSSQSSGYGRQGSGSGQSPGHGQ RGSGSRQSPSYGRHGSGSGRSSSSGQHGSGLGESSGFGHHESSSGQSSSY SQHGSGSGHSSGYGQHGSRSGQSSRGERHGSSSRSSSRYGQHGSGSRQSS GHGRQGSGSGQSPSRGRHGSGLGHSSSHGQHGSGSGRSSSRGPYESRSGH SSVFGQHESGSGHSSAYSQHGSGSGHFCSQGQHGSTSGQSSTFDQEGSST GQSSSHGQHGSGSSQSSSYGQQGSGSGQSPSRGRHGSGSGHSSSYGQHGS GSGWSSSSGRHGSGSGQSSGFGHHESSSWQSSGYTQHGSGSGHSSSYEQH GSRSGQSSRGEQHGSSSGSSSSYGQHGSGSRQSLGHGQHGSGSGQSPSPS RGRHGSGSGQSSSYGPYGSGSGWSSSRGPYESGSGHSSGLGHRESRSGQS SGYGQHGSSSGHSSTHGQHGSASGQSSSCGQHGASSGQSSSHGQHGSGSS QSSGYGRQGSGSGQSPGHGQRGSGSRQSPSYGRHGSGSGRSSSSGQHGPG LGESSGFGHHESSSGQSSSYSQHGSGSGHSSGYGQHGSRSGQSSRGERHG SSSGSSSRYGQHGSGSRQSSGHGRQGSGSGHSPSRGRHGSGSGHSSSHGQ HGSGSGRSSSRGPYESRSGHSSVFGQHESGSGHSSAYSQHGSGSGHFCSQ GQHGSTSGQSSTFDQEGSSTGQSSSHGQHGSGSSQSSSYGQQGSGSGQSP SRGRHGSGSGHSSSYGQHGSGSGWSSSSGRHGSGSGQSSGFGHHESSSWQ SSGYTQHGSGSGHSSSYEQHGSRSGQSSRGERHGSSSGSSSSYGQHGSGS RQSLGHGQHGSGSGQSPSPSRGRHGSGSGQSSSYSPYGSGSGWSSSRGPY ESGSGHSSGLGHRESRSGQSSGYGQHGSSSGHSSTHGQHGSTSGQSSSCG QHGASSGQSSSHGQHGSGSSQSSGYGRQGSGSGQSPGHGQRGSGSRQSPS YGRHGSGSGRSSSSGQHGSGLGESSGFGHHESSSGQSSSYSQHGSGSGHS SGYGQHGSRSGQSSRGERHGSSSGSSSHYGQHGSGSRQSSGHGRQGSGSG QSPSRGRHGSGLGHSSSHGQHGSGSGRSSSRGPYESRLGHSSVFGQHESG SGHSSAYSQHGSGSGHFCSQGQHGSTSGQSSTFDQEGSSTGQSSSYGHRG SGSSQSSGYGRHGAGSGQSLSHGRHGSGSGQSSSYGQHGSGSGQSSGYSQ HGSGSGQDGYSYCKGGSNHDGGSSGSYFLSFPSSTSPYEYVQEQRCYFYQ Little is known about this protein. It has not been studied in the context of myocardial ischemia or events leading up to MI. S. Kininogen

-   Name: ISOFORM LMW OF KININOGEN-1 -   IPI ID: IPI00215894 -   UniProtKB/Swiss-Prot ID: P01042 -   Length: 427 aa, molecular weight: 47883 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION (1) Kininogens are inhibitors of thiol proteases; (2) HMW-kininogen plays an important role in blood coagulation by helping to position optimally prekallikrein and factor XI next to factor XII; (3) HMW-kininogen inhibits the thrombin- and plasmin-induced aggregation of thrombocytes; (4) the active peptide bradykinin that is released from HMW-kininogen shows a variety of physiological effects: (4A) influence in smooth muscle contraction, (4B) induction of hypotension, (4C) natriuresis and diuresis, (4D) decrease in blood glucose level, (4E) it is a mediator of inflammation and causes (4E1) increase in vascular permeability, (4E2) stimulation of nociceptors (4E3) release of other mediators of inflammation (e.g. prostaglandins), (4F) it has a cardioprotective effect (directly via bradykinin action, indirectly via endothelium-derived relaxing factor action); (5) LMW-kininogen inhibits the aggregation of thrombocytes; (6) LMW-kininogen is in contrast to HMW-kininogen not involved in blood clotting. SUBCELLULAR Secreted, extracellular space. LOCATION 2. Sequence

(SEQ ID NO: 19) MKLITILFLCSRLLLSLTQESQSEEIDCNDKDLFKAVDAALKKYNSQNQS NNQFVLYRITEATKTVGSDTFYSFKYEIKEGDCPVQSGKTWQDCEYKDAA KAATGECTATVGKRSSTKFSVATQTCQITPAEGPVVTAQYDCLGCVHPIS TQSPDLEPILRHGIQYFNNNTQHSSLFMLNEVKRAQRQVVAGLNFRITYS IVQTNCSKENFLFLTPDCKSLWNGDTGECTDNAYIDIQLRIASFSQNCDI YPGKDFVQPPTKICVGCPRDIPTNSPELEETLTHTITKLNAENNATFYFK IDNVKKARVQVVAGKKYFIDFVARETTCSKESNEELTESCETKKLGQSLD CNAEVYVVPWEKKIYPTVNCQPLGMISLMKRPPGFSPFRSSRIGEIKEET TSHLRSCEYKGRPPKAGAEPASEREVS 3. Alternative Name(s): High molecular weight kininogen, Short name=HMWK; Williams-Fitzgerald-Flaujeac factor; Fitzgerald factor; Alpha-2-thiol proteinase inhibitor

This protein has not been studied in the context of myocardial ischemia or events leading up to MI.

Example III Further Studies to Identify Cardiac Biomarkers, Using as a Cohort of Patients, a Valve Replacement Cardioplegia Human Model (Cohort II)

A. Overview of the Studies

The 21 patients in this cohort all underwent aortic valve replacement surgery (See FIGS. 6 and 7). Table 10 provides cohort information of this model.

TABLE 10 patient sampling T1 pre-op sample (before incision). T2 immediately before the heart gets stopped (prior to CPB). T6 5 min after the heart went off CPB and was beating on its own again. T7 30 min after bypass T8 60 min after bypass T9 120 min after bypass There were 6 plasma samples taken. Note that only 19 (out of 21) patients have samples at T9. The sample were normalized to total protein concentration for both targeted and de nova discovery. In the targeted analysis, 15 biomarkers were determined for each sample, specifically, CRP, GM-CSF, IFNγ, IL10, IL12p70, IL1β, IL-2, IL-6, IL-8, NT proBNP, SAA, TNFα, cTnI, sICAM, sVCAM. All time points were analyzed. These analyses were done using the MESOSCALE multiplex assay in triplicate. FIG. 7 shows the box blot for cTnI measurement for all patients. For de novo discovery, only T2 and T6 were analyzed. B. Methods 1. High Abundant Protein Depletion

IgY depletion of the top 12 abundant proteins of samples from each individual sample.

2. Intact Protein Separation by Hydrophobicity

1DLC analysis was carried out for cohort II (20 patients with two time points). All 1DLC analyses were done in duplicate using the optimized gradient developed to eliminate the interference of the unknown contaminates that eluted at the beginning and end of the run. Optimization was required as the contaminants were not MS compatible and co-eluted with proteins found to be interesting in cohort I. The duplicate run for each patient time point were collected into a single plate and stored at −80° C. until analyzed. A total of 80@ 1DLC runs were carried out (20×2×2=80 (2 time points, 20 patients, in duplicate)). The fractions obtained for each 1DLC run were pooled into 16 fractions, neutralized and dried down, prior to resolublization in buffer compatible for tryptic digestion.

3. MS Analysis

MS, analysis for each digested fraction was carried using the LTQ Orbitrap LC MSMS instrument. Each fraction was run in duplicate. A total 1216 MS runs were carried out (19×2×16×2=1216 (19 patients, 16 fractions per time point, two time points, in duplicate). For LC-MS/MS experiments on the LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.), peptides were dissolved in 6 μl resuspension buffer (4% acetonitrile in water with 0.1% formic acid). Samples (3 μl) were loaded onto a 75 um×10 cm BioBasic C18 column (New Objective, Woburn, Mass.). Peptides were eluted into an LTQ-Orbitrap (ThermoFinnigan, San Jose, Calif.) using an Agilent 1200 nano-LC system (Agilent, Santa Clara, Calif.). The HPLC gradient was 5% to 60% B (90% acetonitrile/water in 0.1% Formic acid) over 30 or 60 min depended on sample complexity. The mass spectrometer was operated in data-dependent mode in which every FT-MS scan (survey 350-2000 Da) was followed by MS/MS scans of the 5 most abundant ions.

Mass spectrometry data were analyzed, and data reanalysis was carried out, as described in Example 1D2 above.

C. Results

1. Optimization of 1DLC

In order for cohort II to be analyzed, optimization of the 1DLC gradient was required to resolve a contaminating peak eluting early on the chromatogram. The contaminating peak overlaid a region in which we found several potential biomarkers and resulted in suppression of the peptides of interest.

2. Optimization and Testing of Reproducibility of Ms Analysis

In table 11, the MS reproducibility of several fractions is shown.

TABLE 11 MS reproducibility cohort II sequential. MS run 1 vs. run 2 Same LC fraction, digested, split and MS analyzed Method for cohort II run 1 run 2 run 1 run 2 Fraction 1 # # # total # total peptides peptides spectra spectra Protein name Frac- frac- Frac- Frac- tion 1 tion 1 tion 1 tion 1 histidine-rich glycoprotein 14 13 35 32 factor H 12 11 27 24 Kininogen 1 10 11 15 18 complement component 4 8 10 14 19 binding protein Lactoferrin 7 8 16 14 apolipoprotein H 5 4 12 13 Transferrin 5 5 20 18 alpha-1-acid glycoprotein 1 4 4 13 11 haptoglobin 3 4 6 7 fibrinogen, alpha p 3 3 5 5 plasminogen 3 3 6 6 Alpha-1B-glycoprotein 2 0 2 0 alpha2-HS glycoprotein 2 2 3 3 collagen 1 pro-alpha-2 chain 2 1 3 2 selenoprotein P 2 2 5 6 Extracellular matrix protein 1 2 2 3 4 Fraction 2 # # # total # total peptides peptides spectra spectra Protein name Frac- Frac- Frac- Frac- tion 2 tion 2 tion 2 tion 2 complement component C4 27 26 49 47 Antithrombin 22 20 52 78 complement component 3 22 24 42 50 Fibronectin 1 21 24 38 55 Ceruloplasmin 19 21 49 52 Inter-alpha-trypsin inhibitor heavy 14 12 29 25 chain H4 Inter-alpha-trypsin inhibitor heavy 13 15 29 30 chain H2 Alpha-1B-glycoprotein 11 10 28 24 Alpha1 Antichymotrypsin 10 11 46 50 Complement factor B 9 11 23 28 gelsolin isoform b 9 9 19 16 leucine-rich alpha-2-glycoprotein 1 9 7 28 16 Inter-alpha-trypsin inhibitor heavy 9 8 28 37 chain H1 Kininogen 8 10 18 20 histidine-rich glycoprotein 7 7 15 13 apolipoprotein A-IV 6 9 12 16 alpha2-HS glycoprotein 5 5 8 9 peroxiredoxin 2 isoform 5 4 10 19 Transthyretin 4 4 9 10 complement component C6 4 2 13 4 lumican 3 3 14 5 carboxypeptidase B2 isoform a 3 2 5 6 preproprotein apolipoprotein H precursor 2 4 6 21 Transferrin 2 2 3 3 amyloid P 2 0 2 0 alpha-1-microglobulin 2 2 4 4 Retinol binding protein 4 2 2 3 4 complement component 8, alpha 2 1 3 1 serine or cysteine proteinase 2 2 2 2 inhibitor complement component 4 binding 1 1 2 1 protein hemoglobin 1 0 3 0 C9 complement protein 1 0 2 0 alpha-1-acid glycoprotein 1 0 0 0 0 complement factor H-related 1 0 1 0 2 alpha-1-antichymotrypsin 0 2 0 8 3. Cohort II Analysis

343 non-redundant proteins were compared. Table 12 shows those proteins which were most significantly increased in T6 compared to T0 for cohort II.

TABLE 12 Target proteins in cohort II Table 12A: Top hits from cohort II clustered based on related protein family. Below listed the number of individuals the protein was elevated in T6 compared to T2 (increased due to induced ischemia). 20 individuals were analyzed. 1. PRDX2 Peroxiredoxin 2 - increased in 17 patients 2. S100A9 Protein S100-A9 - increased in 17 patients S100 A8 - increased in 11 patients S100 A7 - increased in 4 patients 3. Lactotransferrin increased in 14 patients 4. CA1 Carbonic anhydrase 1 - increased in 17 patients CA2 Carbonic anhydrase 2 - increased in 3 patients 5. Conserved hypothetical protein - increased in 12 patients 6. NCOR2 CTG26 alternate open reading frame (Fragment) - increased in 11 patients 7. LOC729968 Conserved hypothetical protein - increased in 11 patients 8. Conserved hypothetical protein - increased in 9 patients 9. SORL1 Sortilin-related receptor - increased in 11 patients 10. COL1A1 Collagen alpha-1(I) chain precursor - increased in 11 patients COL1A2 130 kDa protein - increased in 10 patients 11. CPB2 Isoform 1 of Carboxypeptidase B2 precursor - increased in 10 patients Carboxypeptidase subunit 2 - increased in 8 patients 12. HBB Hemoglobin subunit beta - increased in 12 patients HBA Hemoglobin subunit alpha - increased in 4patients 13. Lactotransferrin - increased in 12 patients 14. LRP1 Prolow-density lipoprotein receptor-related protein 1 precursor - increased in 9 patients LRP2 Low-density lipoprotein receptor-related protein 2 precursor - increased in 9 patients Together a total of 13 unique patients 15. CAT Catalase - increased in 11 patients 16. STX3 Isoform A of Syntaxin-3 - increased in 9 patients 17. ECM1 Extracellular matrix protein 1 - increased in 10 patients 18. SERPINA10 Protein Z-dependent protease inhibitor precursor - increased in 8 patients 19. PTPRK Isoform 1 of Receptor-type tyrosine-protein phosphatase kappa precursor increased in 8 patients 20. ATRN Isoform 2 of Attractin precursor - increased in 8 patients 21. PTPRK Protein tyrosine phosphatase, receptor type, K increased in 6 patients Table 12B: Others of interest due to biology (there are low abundant proteins and may not be observed in higher number of patients due to detection issues) 22. MST1 Hepatocyte growth factor-like protein precursor - increased in 7 patients HGFAC Hepatocyte growth factor activator precursor - increased in 4 patients 23. IGFBP6 Insulin-like growth factor-binding protein 6 precursor - increased in 5 patients IGFBP5 Insulin-like growth factor-binding protein 5 precursor - increased in 1 patients IGFBP2 Insulin-like growth factor-binding protein 2 precursor - increased in 7 patients (same ones as 7) IGFBP7 Insulin-like growth factor-binding protein 7 precursor - increased in 7 patients (same ones as 2) IGFALS Insulin-like growth factor-binding protein complex acid labile chain precursor - increased in 3 patients Total for group 8 patients 24. SERPINF1 Pigment epithelium-derived factor precursor - increased in 4 patients 25. GPX3 Glutathione peroxidase 3 precursor - increased in 4 patients 26. CD14 Monocyte differentiation antigen CD14 precursor - increased in 4 patients 27. Note there are interesting proteins seen in 2-3 patients which may still be important alternations which are not seen in more patients due to their low abundance. These should be discussed.

A summary of some of the properties of these proteins is presented in Example IV.

4. Cohort II and I Comparison

Comparison of the top candidate proteins between cohort I and II are shown in Table 13.

TABLE 13 Is protein Protein IPI number Cohort I Cohort II FUNCTION secreted? Tier One Lumican IPI00020986 Top Found May be involved in cell Yes response to injury Extracellular matrix IPI00645849 Top Found Involved in extracellular Yes protein matrix compostition Carboxypeptidase IPI00010295 Mid Found Protease involved in Yes N catalytic chain regulation of vasoactive and inflammatory peptides angiogenin IPI00008554 Top no May be involved in Yes angiogeneisis semenogelin IPI00414684 Top no Forms gel matrix around Yes sperm, unknown role in other cells Lung PLNECA-1 IPI00291410 Top no May play a role in innate Yes immunity Perioxiredoxin 2 IPI00027350 No Elevated Involved in redox regulation of No in 17, Top the cell. S100 A9 IPI00027462 No Elevated Expressed by macrophages in No in 17, Top acutely inflamed tissues and in chronic inflammations. S100 A8 IPI00007047 No Elevated Expressed by macrophages in unknown in 11, Top chronic inflammations. Also expressed in epithelial cells constitutively or induced during dermatoses. S100 A7 IPI00219806 No Elevated unknown Secreted in 4, Lower Sortilin-related IPI00022608 No Elevated Likely to be a multifunctional No, is a plasma receptor in 11, Mid endocytic receptor, which membrane protein implicates it in the uptake of lipoproteins and of proteases. Catalase IPI00465436 No Elevated Serves to protect cells from the No in 11, Mid toxic effects of hydrogen peroxide. Low density IPI00020557 No Elevated Endocytic receptor involved in No lipoprotein receptor in 9, Mid endocytosis and in phagocytosis related protein 1 of apoptotic cells. Low density IPI00024292 No Elevated Acts together with cubilin to No lipoprotein receptor in 9, Top mediate HDL endocytosis (By related protein 2 similarity). Syntaxin-3 IPI00395768 No Evelated Potentially involved in docking of No in 9, Mid synaptic vesicles at presynaptic active zones. Tier two Hepatocyte growth IPI00292218 + Unknown Unknown factor like protein Hepatocyte growth IPI00029193 + Activates hepatocyte growth Secreted. factor activator factor (HGF). Insulin like growth IPI00029235 + GF-binding proteins prolong the Secreted. factor protein 6 half-life of the IGFs. Pigment epithelium- IPI00006114 + Neurotrophic protein; induces Secreted. derived factor extensive neuronal differentiation in retinoblastoma cells. Potent inhibitor of angiogenesis. Glutathione IPI00026199 + Protects cells and enzymes from Secreted. peroxidase 3 oxidative damage. Monocyte IPI00029260 + Involved in the innate immune No differentiation response to bacterial antigen CD14 lipopolysaccharide (LPS). Lactotransferrin, IPI00789477 + unknown unknown cDNA FLJ58679, highly similar to Lactotransferrin Attractin IPI00162735 Involved in the initial immune cell Secreted clustering during inflammatory response. Conserved IPI00883661 + Unknown Unknown hypothetical protein NCOR2 CTG26 IPI00006659 + unknown unknown alternate open reading frame LOC729968 IPI00884334 + unknown unknown Conserved hypothetical protein Protein Z- IPI00007199 + Inhibits factor Xa activity. Secreted. dependent protease inhibitor Conserved IPI00847894 unknown unknown hypothetical protein Isoform 1 of IPI00015756 + Regulation of processes No, but present Receptor-type involving cell contact and on plasma tyrosine-protein adhesion such as growth control, membrane phosphatase kappa tumor invasion, and metastasis. Protein tyrosine IPI00552690 + Receptor Unknown, but phosphatase, present on receptor type, K plasma membrane Sodium channel IPI00217376 Elevated Part of sodium channel No, but present subunit beta-4 in 7 on plasma people membrane Alpha2-HS- IPI00022431 + Elevated See previous write up for See previous glycoprotein in 4 cohort I write up for people cohort I Galectin 7 IPI00219221 + − See previous write up for See previous cohort I write up for cohort I Homerin IPI00398625 + Elevated See previous write up for See previous and seen cohort I write up for only in cohort I one person Proteoglycan 4 IPI00655676 + Elevated See previous write up for See previous (isoforms A and D) in 4 cohort I write up for people cohort I Proflaggrin IPI00654788 + − See previous write up for See previous (Filaggrin) cohort I write up for cohort I Vitamin D binding IPI00555812 + − See previous write up for See previous protein cohort I write up for cohort I C4b binding IPI00021727 + − See previous write up for See previous proteins cohort I write up for cohort I Thyroxine binding IPI00292946 + − See previous write up for See previous globulin cohort I write up for cohort I Alpha 2 IPI00166729 + Elevated See previous write up for See previous glycoprotein 1, zinc in 3 cohort I write up for people cohort I Caspase 14 + See previous write up for See previous cohort I write up for cohort I Desmogelin + See previous write up for See previous cohort I write up for cohort I Kininogen-1 IPI00215894 + See previous write up for See previous cohort I write up for cohort I

Some additional proteins were found to be elevated in a subset of the patients in cohort II that exhibit ischemia. See Table 14 below for details.

TABLE 14 # individal with ischemic Protein induced accession increase Protein name numbers (max. 20) PRDX2 Peroxiredoxin-2 IPI00027350 17 S100A9 Protein S100-A9 IPI00027462 17 LTF Similar to Lactotransferrin IPI00789477 14 Conserved hypothetical protein IPI00883661 12 HBB Hemoglobin subunit beta IPI00654755 12 NCOR2 CTG26 alternate open reading IPI00006659 11 frame S100A8 Protein S100-A8 IPI00007047 11 SORL1 Sortilin-related receptor IPI00022608 11 CA1 Carbonic anhydrase 1 IPI00215983 11 COL1A1 Collagen alpha-1(I) chain IPI00297646 11 CAT Catalase IPI00465436 11 ALB Isoform 1 of Serum albumin IPI00745872 11 LOC729968 Conserved hypothetical protein IPI00884334 11 CFI Complement factor I IPI00291867 10 CPB2 Isoform 1 of Carboxypeptidase B2 IPI00329775 10 Ig heavy chain V-II region OU IPI00382534 10 Ig kappa chain V-I region Ka IPI00387095 10 COL1A2 130 kDa protein IPI00873137 10 ECM1 Extracellular matrix protein 1 IPI00645849 10 LRP1 Prolow-density lipoprotein receptor- IPI00020557 9 related protein 1 LRP2 Low-density lipoprotein receptor- IPI00024292 9 related protein 2 C7 Complement component C7 IPI00296608 9 STX3 Isoform A of Syntaxin-3 IPI00395768 9 SERPINA1 Isoform 1 of Alpha-1-antitrypsin IPI00553177 9 LOC440786 Ig kappa chain V-II region IPI00736885 9 TEW Conserved hypothetical protein IPI00847894 9 SERPINA10 Protein Z-dependent protease IPI00007199 8 inhibitor PTPRK Isoform 1 of Receptor-type IPI00015756 8 tyrosine-protein phosphatase kappa AMBP AMBP protein IPI00022426 8 TF Serotransferrin IPI00022463 8 C5 Complement C5 IPI00032291 8 ATRN Isoform 2 of Attractin IPI00162735 8 C1QB complement component 1, q IPI00477992 8 subcomponent, B chain CPN2 Carboxypeptidase N subunit 2 IPI00479116 8 SERPINA5 Plasma serine protease inhibitor IPI00007221 7 LUM Lumican IPI00020986 7 APOB Apolipoprotein B-100 IPI00022229 7 C1QC Complement C1q subcomponent IPI00022394 7 subunit C SHBG Isoform 1 of Sex hormone-binding IPI00023019 7 globulin SCN4B Isoform 1 of Sodium channel IPI00217376 7 subunit beta-4 MST1 Hepatocyte growth factor-like protein IPI00292218 7 MDFI 19 kDa protein IPI00385435 7 QSOX1 Isoform 2 of Sulfhydryl oxidase 1 IPI00465016 7 FETUB GUGU beta form IPI00552199 7 SEPP1 selenoprotein P isoform 2 IPI00847381 7 HBA2; HBA1 Alpha 2 globin variant IPI00853068 7 (Fragment) CPN1 Carboxypeptidase N catalytic chain IPI00010295 6 AFM Afamin IPI00019943 6 SOD1 Superoxide dismutase IPI00218733 6 VTN Vitronectin IPI00298971 6 SERPINA4 Kallistatin IPI00328609 6 SERPINA4 Kallistatin IPI00328609 6 PTPRK Protein tyrosine phosphatase, IPI00552690 6 receptor type, K SERPINA3 Isoform 1 of Alpha-1- IPI00847635 6 antichymotrypsin OU domain class 5 transcription factor 1 IPI00868800 6 (Fragment) ORM1 orosomucoid 1 IPI00884926 6 F12 Coagulation factor XII IPI00019581 5 APOA1 Apolipoprotein A-I IPI00021841 5 IGFBP6 Insulin-like growth factor-binding IPI00029235 5 protein 6 FN1 Isoform 3 of Fibronectin IPI00339223 5 g heavy chain V-III region CAM IPI00382482 5 LOC388720 similar to ubiquitin and IPI00397808 5 ribosomal protein S27a CLU clusterin isoform 1 IPI00400826 5 BTD Uncharacterized protein BTD IPI00744685 5 (Fragment) PROS1 80 kDa protein IPI00873445 5 SERPINF1 Pigment epithelium-derived IPI00006114 4 factor C8G Complement component C8 gamma IPI00011261 4 chain ORM1 Alpha-1-acid glycoprotein 1 IPI00022429 4 AHSG Alpha-2-HS-glycoprotein IPI00022431 4 GGH Gamma-glutamyl hydrolase IPI00023728 4 EFNB1 Ephrin-B1 IPI00024307 4 GPX3 Glutathione peroxidase 3 IPI00026199 4 HGFAC Hepatocyte growth factor activator IPI00029193 4 CD14 Monocyte differentiation antigen IPI00029260 4 CD14 FGA Isoform 2 of Fibrinogen alpha chain IPI00029717 4 LRP1B Similar to Candidate tumor IPI00032063 4 suppressor protein S100A7 Protein S100-A7 IPI00219806 4 C8B Complement component C8 beta chain IPI00294395 4 DMXL1 DmX-like protein 1 IPI00294728 4 ARSB Arylsulfatase B IPI00306576 4 LRP8 Isoform 3 of Low-density lipoprotein IPI00384247 4 receptor-related protein 8 HBA2; HBA1 Hemoglobin subunit alpha IPI00410714 4 ASPN ASPN protein IPI00418431 4 A2M Alpha-2-macroglobulin IPI00478003 4 CDH3 Isoform 2 of Cadherin-3 IPI00645614 4 KLKB1 Plasma kallikrein IPI00654888 4 SERPINA1 Isoform 2 of Alpha-1-antitrypsin IPI00790784 4 ICAM2 28 kDa protein IPI00793958 4 C1RL cDNA FLJ14022 fis, clone IPI00795055 4 HEMBA1003538, weakly similar to COMPLEMENT C1R COMPONENT B2M B2M protein IPI00796379 4 APOA1 Apolipoprotein A1 IPI00853525 4 Transthyretin IPI00855916 4 ITIH3 Uncharacterized protein ITIH3 IPI00873416 4 MB 16 kDa protein IPI00878623 4 SERPINF2 Alpha-2-antiplasmin IPI00879231 4 COL5A2 Collagen alpha-2(V) chain IPI00844306 4 JUP Junction plakoglobin IPI00554711 4 PRG4 Isoform D of Proteoglycan-4 IPI00655676 4 GPR37 Probable G-protein coupled receptor IPI00006166 3 37 F13B Coagulation factor XIII B chain IPI00007240 3 CLEC3B Tetranectin IPI00009028 3 C6 Complement component 6 IPI00009920 3 C8A Complement component C8 alpha IPI00011252 3 chain DSP Isoform DPI of Desmoplakin IPI00013933 3 COPS2 Isoform 2 of COP9 signalosome IPI00018813 3 complex subunit 2 F2 Prothrombin (Fragment) IPI00019568 3 IGFALS Insulin-like growth factor-binding IPI00020996 3 protein complex acid labile chain ACTG1 Actin, cytoplasmic 2 IPI00021440 3 FGA Isoform 1 of Fibrinogen alpha chain IPI00021885 3 RBP4 Plasma retinol-binding protein IPI00022420 3 RBP4 Retinol binding protein 4, plasma IPI00022420 3 HPX Hemopexin IPI00022488 3 NPR1 Atrial natriuretic peptide receptor A IPI00027200 3 SEPP1 Selenoprotein P IPI00029061 3 ZAK Isoform 2 of Mitogen-activated protein IPI00029643 3 kinase kinase kinase MLT CST3 Cystatin-C IPI00032293 3 AZGP1 alpha-2-glycoprotein 1, zinc IPI00166729 3 CA2 Carbonic anhydrase 2 IPI00218414 3 SELL L-selectin IPI00218795 3 FGG Isoform Gamma-A of Fibrinogen IPI00219713 3 gamma chain IGSF5 Immunoglobulin superfamily IPI00245940 3 member 5 LYVE1 Lymphatic vessel endothelial IPI00290856 3 hyaluronic acid receptor 1 SERPING1 Plasma protease C1 inhibitor IPI00291866 3 C17orf13; ACYP1; C1R Complement C1r IPI00296165 3 subcomponent F9 Coagulation factor IX IPI00296176 3 FGB Fibrinogen beta chain IPI00298497 3 LILRB2 leukocyte immunoglobulin-like IPI00303952 3 receptor, subfamily B, member 2 isoform 1 IGHG1 Putative uncharacterized protein IPI00384938 3 DKFZp686N02209 cDNA FLJ43303 fis, clone IPI00445889 3 NOVAR2000136, moderately similar to Calsequestrin, skeletal muscle isoform IGHM IGHM protein IPI00472610 3 PTGDS Prostaglandin D2 synthase 21 kDa IPI00513767 3 GC Vitamin D-binding protein IPI00555812 3 HP Haptoglobin IPI00641737 3 LCN2 Lipocalin 2, Neutrophil gelatinase- IPI00643623 3 associated lipocalin ITIH2 Inter-alpha (Globulin) inhibitor H2 IPI00645038 3 FETUB GUGU beta form, Fetuin-B IPI00743766 3 HABP2 Hyaluronan-binding protein 2 IPI00746623 3 C1S Uncharacterized protein C1S IPI00749179 3 LRP1B Low-density lipoprotein receptor- IPI00877809 3 related protein 1B SERPIND1 Heparin cofactor 2 IPI00879573 3 APOA4 Apolipoprotein A-IV IPI00304273 3 CDH22 Cadherin-22 IPI00000436 2 TAF9 Transcription initiation factor TFIID IPI00002993 2 subunit 9 MBL2 Mannose-binding protein C IPI00004373 2 CRISP3 cDNA FLJ75207 IPI00004798 2 EFNA4 Isoform 1 of Ephrin-A4 IPI00005125 2 COMT Isoform Membrane-bound of IPI00011284 2 Catechol O-methyltransferase LRRC4C Netrin-G1 ligand IPI00014223 2 IGFBP7 Insulin-like growth factor-binding IPI00016915 2 protein 7 C1S Complement C1s subcomponent IPI00017696 2 GGT1 Isoform 1 of Gamma- IPI00018901 2 glutamyltranspeptidase 1 PLG Plasminogen IPI00019580 2 ORM2 Alpha-1-acid glycoprotein 2 IPI00020091 2 PLXNA3 Plexin-A3 IPI00020884 2 C4BPA C4b-binding protein alpha chain IPI00021727 2 SERPINB3 Serpin B3 IPI00022204 2 BAI1 Brain-specific angiogenesis inhibitor 1 IPI00022333 2 HRG Histidine-rich glycoprotein IPI00022371 2 APCS Serum amyloid P-component IPI00022391 2 C1QA Complement C1q subcomponent IPI00022392 2 subunit A C9 Complement component C9 IPI00022395 2 NRGN Neurogranin IPI00022640 2 CDH1 Epithelial cadherin IPI00025861 2 SOD3 Extracellular superoxide dismutase IPI00027827 2 [Cu—Zn] KNG1 Isoform HMW of Kininogen-1 IPI00032328 2 PTH2 Tuberoinfundibular peptide of 39 IPI00059307 2 residues PTPRU protein tyrosine phosphatase, IPI00107472 2 receptor type, U isoform 3 PTPRF Receptor-type tyrosine-protein IPI00107831 2 phosphatase F UBA52 ubiquitin and ribosomal protein IPI00179330 2 L40, UBB; RPS27A; UBC ubiquitin and ribosomal protein S27a UBB; RPS27A; UBC ubiquitin and IPI00179330 2 ribosomal protein S27a TTN Isoform 7 of Titin IPI00179357 2 CLCN6 Isoform A of Chloride channel IPI00180121 2 protein 6 HIST1H1C Histone H1.2 IPI00217465 2 MB Myoglobin IPI00217493 2 HRC Sarcoplasmic reticulum histidine-rich IPI00219226 2 calcium-binding protein SP140 Isoform LYSp100-A of Nuclear body IPI00219535 2 protein SP140 PTPRO Receptor-type tyrosine-protein IPI00241041 2 phosphatase O CLU Clusterin IPI00291262 2 SLC44A2 Isoform 2 of Choline transporter- IPI00293074 2 like protein 2 ITIH4 Isoform 1 of Inter-alpha-trypsin IPI00294193 2 inhibitor heavy chain H4 IGFBP2 Insulin-like growth factor-binding IPI00297284 2 protein 2 LTF Growth-inhibiting protein 12 IPI00298860 2 LCN2 Neutrophil gelatinase-associated IPI00299547 2 lipocalin THBS4 Thrombospondin-4 IPI00328550 2 Ig heavy chain V-III region TEI IPI00382494 2 VASN Vasorin IPI00395488 2 FLG2 Ifapsoriasin IPI00397801 2 SEMG1 Isoform 2 of Semenogelin-1 IPI00414684 2 IGHG1 Putative uncharacterized protein IPI00423466 2 DKFZp686N02209 HUWE1 Isoform 2 of E3 ubiquitin-protein IPI00445401 2 ligase HUWE1 PTPRK Protein tyrosine phosphatase, IPI00470937 2 receptor type, K HP HP protein IPI00478493 2 FCGR3A Fc fragment of IgG, low affinity IPI00640044 2 IIIa, receptor for C2 Complement component 2 IPI00643506 2 CPN2 similar to Carboxypeptidase N IPI00738433 2 subunit 2 A1BG alpha 1B-glycoprotein IPI00745089 2 LOC732428 Uncharacterized protein IPI00787862 2 ENSP00000375150 SOD1 Uncharacterized protein SOD1 IPI00789078 2 CLEC3B Putative uncharacterized protein IPI00792115 2 DKFZp686H17246 8 kDa protein IPI00792845 2 FCGR3B Protein IPI00795501 2 C5 Complement component 5 variant IPI00816741 2 (Fragment) PRAP1 Isoform 4 of Proline-rich acidic IPI00855875 2 protein 1 SH3BGRL 13 kDa protein IPI00872670 2

Example IV Summary of Some of the Properties of Proteins Discussed with Regard to Cohort II

A. Pigment Epithelium-Derived Factor

-   Name: PIGMENT EPITHELIUM-DERIVED FACTOR -   IPI ID: IPI00006114 -   UniProtKB/Swiss-Prot ID: P36955 -   Length: 418 aa, molecular weight: 46342 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Neurotrophic protein; induces extensive neuronal differentiation in retinoblastoma cells. Potent inhibitor of angiogenesis. As it does not undergo the S (stressed) to R (relaxed) conformational transition characteristic of active serpins, it exhibits no serine protease inhibitory activity. SUBCELLULAR Secreted. Melanosome. Note = Enriched in stage I LOCATION melanosomes. PTM The N-terminus is blocked. Extracellular phosphorylation enhances antiangiogenic activity. 2. Sequence:

(SEQ ID NO: 20) MQALVLLLCIGALLGHSSCQNPASPPEEGSPDPDSTGALVEEEDPFFKVP VNKLAAAVSNFGYDLYRVRSSMSPTTNVLLSPLSVATALSALSLGAEQRT ESIIHRALYYDLISSPDIHGTYKELLDTVTAPQKNLKSASRIVFEKKLRI KSSFVAPLEKSYGTRPRVLTGNPRLDLQEINNWVQAQMKGKLARSTKEIP DEISILLLGVAHFKGQWVTKFDSRKTSLEDFYLDEERTVRVPMMSDPKAV LRYGLDSDLSCKIAQLPLTGSMSIIFFLPLKVTQNLTLIEESLTSEFIHD IDRELKTVQAVLTVPKLKLSYEGEVTKSLQEMKLQSLFDSPDFSKITGKP IKLTQVEHRAGFEWNEDGAGTTPSPGLQPAHLTFPLDYHLNQPFIFVLRD TDTGALLFIGKILDPRGP 3. Alternative Name(s): Serpin-F1, EPC-1

Has been used in treatment of retinal ischemic injury. As well, increased levels are observed with retinal diseases and diabetes but none have been related to heart disease including myocardial ischemia.

B. Protein S100-A7

-   Name: Protein S100-A7 -   IPI ID: IPI00219806 -   UniProtKB/Swiss-Prot ID: P31151 -   Length: 101 aa, molecular weight: 11471 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:

Subcellular location Cytoplasm. Secreted. Subunit structure Interacts with RANBP9. 2. Sequence:

(SEQ ID NO: 21) MSNTQAERSIIGMIDMFHKYTRRDDKIEKPSLLTMMKENFPNFLSACDKK GTNYLADVFEKKDKNEDKKIDFSEFLSLLGDIATDYHKQSHGAAPCSGGS Q 3. Alternative Name(s): S100 Calcium-Binding Protein A7; Psoriasin

This protein has not been linked to myocardial ischemia or events leading up to MI.

C. Protein S100-A8

-   Name: Protein S100 A8 -   IPI ID: IPI00007047 -   UniProtKB/Swiss-Prot ID: P05109 -   Length: 93 aa, molecular weight: 10835 Da     1. Basic information from UniProtKB/Swiss-Prot entry:     -   Function: Expressed by macrophages in chronic inflammations.         Also expressed in epithelial cells constitutively or induced         during dermatoses. May interact with components of the         intermediate filaments in monocytes and epithelial cells.         2. Sequence:

(SEQ ID NO: 22) MLTELEKALNSIIDVYHKYSLIKGNFHAVYRDDLKKLLETECPQYIRKKGA DVWFKELDINTDGAVNFQEFLILVIKMGVAAHKKSHEESHKE 3. Alternative Name(s):

-   -   S100 calcium-binding protein A8         -   Calgranulin-A         -   Migration inhibitory factor-related protein 8             -   Short name=MRP-8             -   Short name=P8         -   Cystic fibrosis antigen             -   Short name=CFAG         -   Leukocyte L1 complex light chain         -   Calprotectin L1L subunit         -   Urinary stone protein band A             This protein has not been linked to myocardial ischemia or             events leading up to MI.             D. Protein S100-A9

-   Name: PROTEIN S100-A9

-   IPI ID: IPI00027462

-   UniProtKB/Swiss-Prot ID: P06702

-   Length: 114 aa, molecular weight: 13242 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:     -   Function: Expressed by macrophages in acutely inflammated         tissues and in chronic inflammations. Seem to be an inhibitor of         protein kinases. Also expressed in epithelial cells         constitutively or induced during dermatoses. May interact with         components of the intermediate filaments in monocytes and         epithelial cells.     -   Subcellular location: cytoplasm and nucleus.         2. Sequence:

(SEQ ID NO: 23) MTCKMSQLERNIETIINTFHQYSVKLGHPDTLNQGEFKELVRKDLQNFLK KENKNEKVIHTMEDLDTNADKQLSFEEFIMLMARLTWASHEKMEIEGDEG PGHHHKPGLGEGTP 3. Alternative Name(s):

-   -   Full=S100 calcium-binding protein A9;     -   Full=Calgranulin-B;     -   Full=Migration inhibitory factor-related protein 14;     -   Short=MRP-14;     -   Short=P14;     -   Full=Leukocyte L1 complex heavy chain;     -   Full=Calprotectin L1H subunit;         The mRNA levels of S100 A9 have been shown to increase after         ischemic brain injury and after stroke. The protein level was         not determined. This protein has not been linked to myocardial         ischemia or events leading up to MI.         E. Protein Tyrosine Phosphatase, Receptor Type, K

-   Name: PROTEIN TYROSINE PHOSPHATASE, RECEPTOR TYPE, K

-   IPI ID: IPI00552690

-   UniProtKB/TrEMBL ID: Q5JY45

-   Length: 202 aa, molecular weight: 22792 Da     Sequence:

(SEQ ID NO: 24) MSSVEKETKTQCVRIATKAAATEEPEVIPDPAKQTDRVVKIAGISAGILV FILLLLVVILIVKKRRSYYSYSYYLKLAKKRKDAMGNTRQEMTHMVNAMD RSYADQSTLHAEDPLSITFMDQHNFSPRLPNDPLVPTAVLDENHSATAES SRLLDVPRYLCEGTESPYQTGQLHPAIRVADLLQHINLMKTSDSYGFKEE YE This protein has not been linked to myocardial ischemia or events leading up to MI. F. Protein Z-Dependent Protease Inhibitor

-   Name: Protein Z-dependent protease inhibitor -   IPI ID: IPI00007199 -   UniProtKB/Swiss-Prot ID: Q9UK55 -   Length: 484 aa, molecular weight: 55114 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Inhibits factor Xa activity in the presence of protein Z, calcium and phospholipid. SUBCELLULAR Secreted. LOCATION 2. Sequence:

(SEQ ID NO: 25) MSRSTQELLGYHCRLQDKLQEQEGSLAAEGRHSLASAADHMKVVPSLLLS VLLAQVWLVPGLAPSPQSPETPAPQNQTSRVVQAPKEEEEDEQEASEEKA SEEEKAWLMASRQQLAKETSNFGFSLLRKISMRHDGNMVFSPFGMSLAMT GLMLGATGPTETQIKRGLHLQALKPTKPGLLPSLFKGLRETLSRNLELGL TQGSFAFIHKDFDVKETFFNLSKRYFDTECVPMNFRNASQAKRLMNHYIN KETRGKIPKLFDEINPETKLILVDYILFKGKWLTPFDPVFTEVDTFHLDK YKTIKVPMMYGAGKFASTFDKNFRCHVLKLPYQGNATMLVVLMEKMGDHL ALEDYLTTDLVETWLRNMKTRNMEVFFPKFKLDQKYEMHELLRQMGIRRI FSPFADLSELSATGRNLQVSRVLQRTVIEVDERGTEAVAGILSEITAYSM PPVIKVDRPFHFMIYEETSGMLLFLGRVVNPTLL 3. Alternative Name(s): Serpin A10

Protein Z was recently shown to act as an essential cofactor for protein Z-dependent protease inhibitor, a potent downregulator of coagulation Factor Xa. Low levels of protein Z have been correlated with increased risk of stroke. However, protein Z dependent protease inhibitor was not studied. This protein has not been linked to myocardial ischemia or events leading up to MI.

G. Sodium Channel Subunit Beta-4

-   Name: ISOFORM 1 OF SODIUM CHANNEL SUBUNIT BETA-4 -   IPI ID: IPI00217376 -   UniProtKB/Swiss-Prot ID: Q8IWT1-1 -   Length: 228 aa, molecular weight: 24969 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Modulates channel gating kinetics. Causes negative shifts in the voltage dependence of activation of certain alpha sodium channels, but does not affect the voltage dependence of inactivation (By similarity). SUBCELLULAR Membrane; Single-pass type I membrane protein LOCATION (Probable). 2. Sequence:

(SEQ ID NO: 26) MPGAGDGGKAPARWLGTGLLGLFLLPVTLSLEVSVGKATDIYAVNGTEIL LPCTFSSCFGFEDLHFRWTYNSSDAFKILIEGTVKNEKSDPKVTLKDDDR ITLVGSTKEKMNNISIVLRDLEFSDTGKYTCHVKNPKENNLQHIIATIFL QVVDRLEEVDNTVTLIILAVVGGVIGLLILILLIKKLIIFILKKTREKKK ECLVSSSGNDNTENGLPGSKAEEKPPSKV This protein has not been linked to myocardial ischemia or events leading up to MI. H. Sortilin-Related Receptor

-   Name: SORTILIN-RELATED RECEPTOR -   IPI ID: IPI00022608 -   UniProtKB/Swiss-Prot ID: Q92673 -   Length: 2214 aa, molecular weight: 248441 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Likely to be a multifunctional endocytic receptor, that may be implicated in the uptake of lipoproteins and of proteases. Binds LDL, the major cholesterol- carrying lipoprotein of plasma, and transports it into cells by endocytosis. Binds the receptor- associated protein (RAP). Could play a role in cell- cell interaction. SUBCELLULAR Membrane; Single-pass type I membrane protein LOCATION (Potential). 2. Sequence:

(SEQ ID NO: 27) MATRSSRRESRLPFLFTLVALLPPGALCEVWTQRLHGGSAPLPQDRGFLV VQGDPRELRLWARGDARGASRADEKPLRRKRSAALQPEPIKVYGQVSLND SHNQMVVHWAGEKSNVIVALARDSLALARPKSSDVYVSYDYGKSFKKISD KLNFGLGNRSEAVIAQFYHSPADNKRYIFADAYAQYLWITFDFCNTLQGF SIPFRAADLLLHSKASNLLLGFDRSHPNKQLWKSDDFGQTWIMIQEHVKS FSWGIDPYDKPNTIYIERHEPSGYSTVFRSTDFFQSRENQEVILEEVRDF QLRDKYMFATKVVHLLGSEQQSSVQLWVSFGRKPMRAAQFVTRHPINEYY IADASEDQVFVCVSHSNNRTNLYISEAEGLKFSLSLENVLYYSPGGAGSD TLVRYFANEPFADFHRVEGLQGVYIATLINGSMNEENMRSVITFDKGGTW EFLQAPAFTGYGEKINCELSQGCSLHLAQRLSQLLNLQLRRMPILSKESA PGLIIATGSVGKNLASKTNVYISSSAGARWREALPGPHYYTWGDHGGIIT AIAQGMETNELKYSTNEGETWKTFIFSEKPVFVYGLLTEPGEKSTVFTIF GSNKENVHSWLILQVNATDALGVPCTENDYKLWSPSDERGNECLLGHKTV FKRRTPHATCFNGEDFDRPVVVSNCSCTREDYECDFGFKMSEDLSLEVCV PDPEFSGKSYSPPVPCPVGSTYRRTRGYRKISGDTCSGGDVEARLEGELV PCPLAEENEFILYAVRKSIYRYDLASGATEQLPLTGLRAAVALDFDYEHN CLYWSDLALDVIQRLCLNGSTGQEVIINSGLETVEALAFEPLSQLLYWVD AGFKKIEVANPDGDFRLTIVNSSVLDRPRALVLVPQEGVMFWTDWGDLKP GIYRSNMDGSAAYHLVSEDVKWPNGISVDDQWIYWTDAYLECIERITFSG QQRSVILDNLPHPYAIAVFKNEIYWDDWSQLSIFRASKYSGSQMEILANQ LTGLMDMKIFYKGKNTGSNACVPRPCSLLCLPKANNSRSCRCPEDVSSSV LPSGDLMCDCPQGYQLKNNTCVKEENTCLRNQYRCSNGNCINSIWWCDFD NDCGDMSDERNCPTTICDLDTQFRCQESGTCIPLSYKCDLEDDCGDNSDE SHCEMHQCRSDEYNCSSGMCIRSSWVCDGDNDCRDWSDEANCTAIYHTCE ASNFQCRNGHCIPQRWACDGDTDCQDGSDEDPVNCEKKCNGFRCPNGTCI PSSKHCDGLRDCSDGSDEQHCEPLCTHFMDFVCKNRQQCLFHSMVCDGII QCRDGSDEDAAFAGCSQDPEFHKVCDEFGFQCQNGVCISLIWKCDGMDDC GDYSDEANCENPTEAPNCSRYFQFRCENGHCIPNRWKCDRENDCGDWSDE KDCGDSHILPFSTPGPSTCLPNYYRCSSGTCVMDTWVCDGYRDCADGSDE EACPLLANVTAASTPTQLGRCDRFEFECHQPKTCIPNWKRCDGHQDCQDG RDEANCPTHSTLTCMSREFQCEDGEACIVLSERCDGFLDCSDESDEKACS DELTVYKVQNLQWTADFSGDVTLTWMRPKKMPSASCVYNVYYRVVGESIW KTLETHSNKTNTVLKVLKPDTTYQVKVQVQCLSKAHNTNDFVTLRTPEGL PDAPRNLQLSLPREAEGVIVGHWAPPIHTHGLIREYIVEYSRSGSKMWAS QRAASNFTEIKNLLVNTLYTVRVAAVTSRGIGNWSDSKSITTIKGKVIPP PDIHIDSYGENYLSFTLTMESDIKVNGYVVNLFWAFDTHKQERRTLNFRG SILSHKVGNLTAHTSYEISAWAKTDLGDSPLAFEHVMTRGVRPPAPSLKA KAINQTAVECTWTGPRNVVYGIFYATSFLDLYRNPKSLTTSLHNKTVIVS KDEQYLFLVRVVVPYQGPSSDYVVVKMIPDSRLPPRHLHVVHTGKTSVVI KWESPYDSPDQDLLYAIAVKDLIRKTDRSYKVKSRNSTVEYTLNKLEPGG KYHIIVQLGNMSKDSSIKITTVSLSAPDALKIITENDHVLLFWKSLALKE KHFNESRGYEIHMFDSAMNITAYLGNTTDNFFKISNLKMGHNYTFTVQAR CLFGNQICGEPAILLYDELGSGADASATQAARSTDVAAVVVPILFLILLS LGVGFAILYTKHRRLQSSFTAFANSHYSSRLGSAIFSSGDDLGEDDEDAP MITGFSDDVPMVIA 3. Alternative Name(s):

-   -   Sorting protein-related receptor containing LDLR class A repeats         -   Short name=SorLA     -   SorLA-1     -   Low-density lipoprotein receptor relative with 11 ligand-binding         repeats         -   Short name=LDLR relative with 11 ligand-binding repeats         -   Short name=LR11             This protein has not been linked to myocardial ischemia or             events leading up to MI.             I. Conserved Hypothetical Protein

-   Name Conserved hypothetical protein

-   IPI ID: IPI00884334

-   Length: 168 aa, molecular weight: 18798 Da     Sequence:

(SEQ ID NO: 28) MRSFLLVWKLFRRKDMKHQRKTATEFKTTEEGETRQDGKDGSLTYRADTC SPCPEAGGPPSSSIASGSSISVGNSPSHSHSHTSRRCGGSSRSRECCSSL HSSRGSRGSSWSSSPPGSTCRWCSCHSHHHSHHRSHHRSHHCSHHHSHHH SGHHSHHNFHNHSNPWCQ This protein has not been linked to myocardial ischemia or events leading up to MI. J. Catalase

-   Name: Catalase -   IPI ID: IPI00465436 -   UniProtKB/Swiss-Prot ID: P04040 -   Length: 527 aa, molecular weight: 59756 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:

Function Occurs in almost all aerobically respiring organisms and serves to protect cells from the toxic effects of hydrogen peroxide. Promotes growth of cells including T-cells, B- cells, myeloid leukemia cells, melanoma cells, mastocytoma cells and normal and transformed fibroblast cells. Subcellular Peroxisome. location 2. Sequence:

(SEQ ID NO: 29) MADSRDPASDQMQHWKEQRAAQKADVLTTGAGNPVGDKLNVITVGPRGPL LVQDVVFTDEMAHFDRERIPERVVHAKGAGAFGYFEVTHDITKYSKAKVF EHIGKKTPIAVRFSTVAGESGSADTVRDPRGFAVKFYTEDGNWDLVGNNT PIFFIRDPILFPSFIHSQKRNPQTHLKDPDMVWDFWSLRPESLHQVSFLF SDRGIPDGHRHMNGYGSHTFKLVNANGEAVYCKFHYKTDQGIKNLSVEDA ARLSQEDPDYGIRDLFNAIATGKYPSWTFYIQVMTFNQAETFPFNPFDLT KVWPHKDYPLIPVGKLVLNRNPVNYFAEVEQIAFDPSNMPPGIEASPDKM LQGRLFAYPDTHRHRLGPNYLHIPVNCPYRARVANYQRDGPMCMQDNQGG APNYYPNSFGAPEQQPSALEHSIQYSGEVRRFNTANDDNVTQVRAFYVNV LNEEQRKRLCENIAGHLKDAQIFIQKKAVKNFTEVHPDYGSHIQALLDKY NAEKPKNAIHTFVQSGSHLAAREKANL

Catalase is an important enzyme in the heart's regulation of oxidative stress. It has been linked to preconditioning in the heart tissue. As a serum marker, it has not been linked to myocardial ischemia or events leading up to MI.

K. Conserved Hypothetical Protein

-   Name: Conserved hypothetical protein -   IPI ID: IPI00883661 -   UniProt/TrEMBL ID: A6NFT5     Length: 175 aa, molecular weight: 20933 Da     2. Sequence:

(SEQ ID NO: 30) MNIHIHTCMHIYTHAHTHAHIHTCIHTHTHMHTHTLTYTHIHMHTHTQ THIYTQAHIHSCTQINIYTYAYTLTCTQTHTHICTHAHTLTYTHIHTC TYKRTYIQGHIHTHMHTYTCTCTHTHKHIHAHIHIHTHTHIYTHTDAY THMDTYTHTYPHTHICIHSHTHAHTYTHIRT This protein has not been linked to myocardial ischemia or events leading up to MI. L. Glutathione Peroxidase 3

-   Name: Glutathione peroxidase 3 -   IPI ID: IPI00026199 -   UniProtKB/Swiss-Prot ID: P22352 -   Length: 226 aa, molecular weight: 25505 Da     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Protects cells and enzymes from oxidative damage, by catalyzing the reduction of hydrogen peroxide, lipid peroxides and organic hydroperoxide, by glutathione. SUBCELLULAR Secreted. LOCATION TISSUE Secreted in plasma. SPECIFICITY 2. Sequence

(SEQ ID NO: 31) MARLLQASCLLSLLLAGFVSQSRGQEKSKMDCHGGISGTIYEYGALTI DGEEYIPFKQYAGKYVLFVNVASYCGLTGQYIELNALQEELAPFGLVI LGFPCNQFGKQEPGENSEILPTLKYVRPGGGFVPNFQLFEKGDVNGEK EQKFYTFLKNSCPPTSELLGTSDRLFWEPMKVHDIRWNFEKFLVGPDG IPIMRWHHRTTVSNVKMDILSYMRRQAALGVKRK 3. Alternative Name(s):

-   -   GSHPx-3         -   Short name=GPx-3     -   Extracellular glutathione peroxidase     -   Plasma glutathione peroxidase     -   GSHPx-P         -   Short name=GPx-P             GPx 3 is an important enzyme involved in many cells             regulation of oxidative stress. As a serum marker it has not             been linked to myocardial ischemia or events leading up to             MI.             M. Hepatocyte Growth Factor Activator

-   Name: HEPATOCYTE GROWTH FACTOR ACTIVATOR

-   IPI ID: IPI00029193

-   UniProtKB/Swiss-Prot ID: Q04756

-   Length: 655 aa, molecular weight: 70682 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Activates hepatocyte growth factor (HGF) by converting it from a single chain to a heterodimeric form. SUBCELLULAR Secreted. Note = Secreted as an inactive LOCATION single-chain precursor and is then activated to a heterodimeric form. 2. Sequence:

(SEQ ID NO: 32) MGRWAWVPSPWPPPGLGPFLLLLLLLLLLPRGFQPQPGGNRTESPEPN ATATPAIPTILVTSVTSETPATSAPEAEGPQSGGLPPPPRAVPSSSSP QAQALTEDGRPCRFPFRYGGRMLHACTSEGSAHRKWCATTHNYDRDRA WGYCVEATPPPGGPAALDPCASGPCLNGGSCSNTQDPQSYHCSCPRAF TGKDCGTEKCFDETRYEYLEGGDRWARVRQGHVEQCECFGGRTWCEGT RHTACLSSPCLNGGTCHLIVATGTTVCACPPGFAGRLCNIEPDERCFL GNGTGYRGVASTSASGLSCLAWNSDLLYQELHVDSVGAAALLGLGPHA YCRNPDNDERPWCYVVKDSALSWEYCRLEACESLTRVQLSPDLLATLP EPASPGRQACGRRHKKRTFLRPRIIGGSSSLPGSHPWLAAIYIGDSFC AGSLVHTCWVVSAAHCFSHSPPRDSVSVVLGQHFFNRTTDVTQTFGIE KYIPYTLYSVFNPSDHDLVLIRLKKKGDRCATRSQFVQPICLPEPGST FPAGHKCQIAGWGHLDENVSGYSSSLREALVPLVADHKCSSPEVYGAD ISPNMLCAGYFDCKSDACQGDSGGPLACEKNGVAYLYGIISWGDGCGR LHKPGVYTRVANYVDWINDRIRPPRRLVAPS This protein has not been linked to myocardial ischemia or events leading up to MI. N. Hepatocyte Growth Factor-Like Protein Homolog

-   Name: HEPATOCYTE GROWTH FACTOR-LIKE PROTEIN HOMOLOG -   IPI ID: IPI00292218 -   UniProtKB/TrEMBL ID: B7Z557 -   Length: 697 aa, molecular weight: 78787 Da     Sequence:

(SEQ ID NO: 33) MLRGPCSPLNDFQVLRGTELQHLLHAVVPGPWQEDVADAEECAGRCGP LMDCRAFHYNVSSHGCQLLPWTQHSPHTRLRRSGRCDLFQKKDYVRTC IMNNGVGYRGTMATTVGGLPCQAWSHKFPNDHKYTPTLRNGLEENFCR NPDGDPGGPWCYTTDPAVRFQSCGIKSCREAACVWCNGEEYRGAVDRT ESGRECQRWDLQHPHQHPFEPGKFLDQGLDDNYCRNPDGSERPWCYTT DPQIEREFCDLPRCGSEAQPRQEATTVSCFRGKGEGYRGTANTTTAGV PCQRWDAQIPHQHRFTPEKYACKDLRENFCRNPDGSEAPWCFTLRPGM RAAFCYQIRRCTDDVRPQDCYHGAGEQYRGTVSKTRKGVQCQRWSAET PHKPQFTFTSEPHAQLEENFCRNPDGDSHGPWCYTMDPRTPFDYCALR RCADDQPPSILDPPDQVQFEKCGKRVDRLDQRRSKLRVVGGHPGNSPW TVSLRNRQGQHFCGGSLVKEQWILTARQCFSSCHMPLTGYEVWLGTLF QNPQHGEPSLQRVPVAKMVCGPSGSQLVLLKLERSVTLNQRVALICLP PEWYVVPPGTKCEIAGWGETKGTGNDTVLNVALLNVISNQECNIKHRG RVRESEMCTEGLLAPVGACEGDYGGPLACFTHNCWVLEGIIIPNRVCA RSRWPAVFTRVSVFVDWIHKVMRLG This protein has not been linked to myocardial ischemia or events leading up to MI O. Insulin-Like Growth Factor-Binding Protein 6

-   Name: INSULIN-LIKE GROWTH FACTOR-BINDING PROTEIN 6 -   IPI ID: IPI00029235 -   UniProtKB/Swiss-Prot ID: P24592 -   Length: 240 aa, molecular weight: 25322 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION IGF-binding proteins prolong the half-life of the IGFs and have been shown to either inhibit or stimulate the growth promoting effects of the IGFs on cell culture. They alter the interaction of IGFs with their cell surface receptors. SUBCELLULAR Secreted. LOCATION 2. Sequence:

(SEQ ID NO: 34) MTPHRLLPPLLLLLALLLAASPGGALARCPGCGQGVQAGCPGGCVEEE DGGSPAEGCAEAEGCLRREGQECGVYTPNCAPGLQCHPPKDDEAPLRA LLLGRGRCLPARAPAVAEENPKESKPQAGTARPQDVNRRDQQRNPGTS TTPSQPNSAGVQDTEMGPCRRHLDSVLQQLQTEVYRGAQTLYVPNCDH RGFYRKRQCRSSQGQRRGPCWCVDRMGKSLPGSPDGNGSSSCPTGSSG 3. Synonym: IBP-6

In a swine model of myocardial injury, studied at 3-24, 72, or 168 hrs, it was shown that there was an increased level of mRNA of IGFBP-6 at all time points. In situ hybridisation identified myocytes as the main producers of IGFBP-6 mRNA. However, the protein itself was not investigated. As well, this protein was found to be elevated in a young multiple myeloma patient with high-output cardiac failure. To date, there has been no study indicating the association of this protein with myocardial ischemia or events leading up to MI.

P. Conserved Hypothetical Protein

-   Name: Conserved hypothetical protein -   IPI ID: IPI00847894 -   Length: 88 aa, molecular weight: 9931 Da     Sequence:

(SEQ ID NO: 35) MFTLRLFAGKACWPVLYTMLKEVTCDVCVCVRARACTCMCMCVCECMD VCVRLYTMLKEVTCDMCVCARTCVHVCVSAWMCVCTCTQC This protein has not been linked to myocardial ischemia or events leading up to MI. Q. Isoform 1 of Receptor-Type Tyrosine-Protein Phosphatase Kappa

-   Name: ISOFORM 1 OF RECEPTOR-TYPE TYROSINE-PROTEIN PHOSPHATASE KAPPA -   IPI ID: IPI00015756 -   UniProtKB/Swiss-Prot ID: Q15262-1 -   Length: 1439 aa, molecular weight: 162102 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Regulation of processes involving cell contact and adhesion such as growth control, tumor invasion, and metastasis. Forms complexes with beta-catenin and gamma-catenin/plakoglobin. Beta-catenin may be a substrate for the catalytic activity of PTP-kappa. SUBCELLULAR Cell junction, adherens junction. Cell membrane; LOCATION Single-pass type I membrane protein. 2. Sequence:

(SEQ ID NO: 36) MDTTAAAALPAFVALLLLSPWPLLGSAQGQFSAGGCTFDDGPGACDYH QDLYDDFEWVHVSAQEPHYLPPEMPQGSYMIVDSSDHDPGEKARLQLP TMKENDTHCIDFSYLLYSQKGLNPGTLNILVRVNKGPLANPIWNVTGF TGRDWLRAELAVSTFWPNEYQVIFEAEVSGGRSGYIAIDDIQVLSYPC DKSPHFLRLGDVEVNAGQNATFQCIATGRDAVHNKLWLQRRNGEDIPV AQTKNINHRRFAASFRLQEVTKTDQDLYRCVTQSERGSGVSNFAQLIV REPPRPIAPPQLLGVGPTYLLIQLNANSIIGDGPIILKEVEYRMTSGS WTETHAVNAPTYKLWHLDPDTEYEIRVLLTRPGEGGTGLPGPPLITRT KCAEPMRTPKTLKIAEIQARRIAVDWESLGYNITRCHTFNVTICYHYF RGHNESKADCLDMDPKAPQHVVNHLPPYTNVSLKMILTNPEGRKESEE TIIQTDEDVPGPVPVKSLQGTSFENKIFLNWKEPLDPNGIITQYEISY SSIRSFDPAVPVAGPPQTVSNLWNSTHHVFMHLHPGTTYQFFIRASTV KGFGPATAINVTTNISAPTLPDYEGVDASLNETATTITVLLRPAQAKG APISAYQIVVEELHPHRTKREAGAMECYQVPVTYQNAMSGGAPYYFAA ELPPGNLPEPAPFTVGDNRTYQGFWNPPLAPRKGYNIYFQAMSSVEKE TKTQCVRIATKAATEEPEVIPDPAKQTDRVVKIAGISAGILVFILLLL VVILIVKKSKLAKKRKDAMGNTRQEMTHMVNAMDRSYADQSTLHAEDP LSITFMDQHNFSPRYENHSATAESSRLLDVPRYLCEGTESPYQTGQLH PAIRVADLLQHINLMKTSDSYGFKEEYESFFEGQSASWDVAKKDQNRA KNRYGNIIAYDHSRVILQPVEDDPSSDYINANYIDGYQRPSHYIATQG PVHETVYDFWRMIWQEQSACIVMVTNLVEVGRVKCYKYWPDDTEVYGD FKVTCVEMEPLAEYVVRTFTLERRGYNEIREVKQFHFTGWPDHGVPYH ATGLLSFIRRVKLSNPPSAGPIVVHCSAGAGRTGCYIVIDIMLDMAER EGVVDIYNCVKALRSRRINMVQTEEQYIFIHDAILEACLCGETAIPVC EFKAAYFDMIRIDSQTNSSHLKDEFQTLNSVTPRLQAEDCSIACLPRN HDKNRFMDMLPPDRCLPFLITIDGESSNYINAALMDSYRQPAAFIVTQ YPLPNTVKDFWRLVYDYGCTSIVMLNEVDLSQGCPQYWPEEGMLRYGP IQVECMSCSMDCDVINRIFRICNLTRPQEGYLMVQQFQYLGWASHREV PGSKRSFLKLILQVEKWQEECEEGEGRTIIHCLNGGGRSGMFCAIGIV VEMVKRQNVVDVFHAVKTLRNSKPNMVEAPEQYRFCYDVALEYLESS This protein has not been linked to myocardial ischemia or events leading up to MI. R. Isoform 2 of Attractin

-   Name: ISOFORM 2 OF ATTRACTIN -   IPI ID: IPI00162735 -   UniProtKB/Swiss-Prot ID: O75882-2 -   Length: 1272 aa, molecular weight: 141429 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Involved in the initial immune cell clustering during inflammatory response and may regulate chemotactic activity of chemokines. May play a role in melanocortin signaling pathways that regulate energy homeostasis and hair color. Low-affinity receptor for agouti (By similarity). Has a critical role in normal myelination in the central nervous system (By similarity). SUBCELLULAR Secreted. LOCATION 2. Sequence:

(SEQ ID NO: 37) MVAAAAATEARLRRRTAATAALAGRSGGPHWDWDVTRAGRPGLGAGLR LPRLLSPPLRPRLLLLLLLLSPPLLLLLLPCEAEAAAAAAAVSGSAAA EAKECDRPCVNGGRCNPGTGQCVCPAGWVGEQCQHCGGRFRLTGSSGF VTDGPGNYKYKTKCTWLIEGQPNRIMRLRFNHFATECSWDHLYVYDGD SIYAPLVAAFSGLIVPERDGNETVPEVVATSGYALLHFFSDAAYNLTG FNITYSFDMCPNNCSGRGECKISNSSDTVECECSENWKGEACDIPHCT DNCGFPHRGICNSSDVRGCSCFSDWQGPGCSVPVPANQSFWTREEYSN LKLPRASHKAVVNGNIMWVVGGYMFNHSDYNMVLAYDLASREWLPLNR SVNNVVVRYGHSLALYKDKIYMYGGKIDSTGNVTNELRVFHIHNESWV LLTPKAKEQYAVVGHSAHIVTLKNGRVVMLVIFGHCPLYGYISNVQEY DLDKNTWSILHTQGALVQGGYGHSSVYDHRTRALYVHGGYKAFSANKY RLADDLYRYDVDTQMWTILKDSRFFRYLHTAVIVSGTMLVFGGNTHND TSMSHGAKCFSSDFMAYDIACDRWSVLPRPDLHHDVNRFGHSAVLHNS TMYVFGGFNSLLLSDILVFTSEQCDAHRSEAACLAAGPGIRCVWNTGS SQCISWALATDEQEEKLKSECFSKRTLDHDRCDQHTDCYSCTANTNDC HWCNDHCVPRNHSCSEGQISIFRYENCPKDNPMYYCNKKTSCRSCALD QNCQWEPRNQECIALPENICGIGWHLVGNSCLKITTAKENYDNAKLFC RNHNALLASLTTQKKVEFVLKQLRIMQSSQSMSKLTLTPWVGLRKINV SYWCWEDMSPFTNSLLQWMPSEPSDAGFCGILSEPSTRGLKAATCINP LNGSVCERPANHSAKQCRTPCALRTACGDCTSGSSECMWCSNMKQCVD SNAYVASFPFGQCMEWYTMSTCPPENCSGYCTCSHCLEQPGCGWCTDP SNTGKGKCIEGSYKGPVKMPSQAPTGNFYPQPLLNSSMCLEDSRYNWS FIHCPACQCNGHSKCINQSICEKCENLTTGKHCETCISGFYGDPTNGG KCQPCKCNGHASLCNTNTGKCFCTTKGVKGDECQLCEVENRYQGNPLR GTCYYTLLIDYQFTFSLSQEDDRYYTAINFVATPDEQNRDLDMFINAS KNFNLNITWAASFSAGTQAGEEMPVVSKTNIKEYKDSFSNEKFDFRNH PNITFFVYVSNFTWPIKIQVQTEQ 3. Alternative Name(s): Mahogany Homolog; DPPT-L This protein has not been linked to myocardial ischemia and events leading up to MI. S. Isoform a of Syntaxin-3

-   Name: Syntaxin-3 (STX3A) -   IPI ID: IPI00395768 -   UniProtKB/Swiss-Prot ID: Q13277-1 and Q13277-2 -   Length: 289 aa, molecular weight: 33155 Da - - - Q13277-1     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Potentially involved in docking of synaptic vesicles at presynaptic active zones. SUBCELLULAR Membrane; Single-pass type IV membrane protein LOCATION (Potential). 2. Sequence:

(SEQ ID NO: 38) MKDRLEQLKAKQLTQDDDTDAVEIAIDNTAFMDEFFSEIEETRLNIDK ISEHVEEAKKLYSIILSAPIPEPKTKDDLEQLTTEIKKRANNVRNKLK SMEKHIEEDEVRSSADLRIRKSQHSVLSRKFVEVMTKYNEAQVDFRER SKGRIQRQLEITGKKTTDEELEEMLESGNPAIFTSGIIDSQISKQALS EIEGRHKDIVRLESSIKELHDMFMDIAMLVENQGEMLDNIELNVMHTV DHVEKARDETKKAVKYQSQARKKLIIIIVLVVVLLGILALIIGLSVGLN This protein has not been linked to myocardial ischemia and events leading up to MI. T. Lactotransferrin

-   Name: Lactotransferrin -   IPI ID: IPI00789477 -   UniProtKB/TrEMBL ID: B2MV14, B7Z4X2 -   Length: 666 aa, molecular weight: 73161 Da     Sequence:

(SEQ ID NO: 39) MRKVRGPPVSCIKRDSPIQCIQAIΛENRADAVTLDGGFIYEAGLAPYK LRPVAAEVYGTERQPRTHYYAVAVVKKGGSFQLNELQGLKSCHTGLRR TAGWNVPIGTLRPFLNWTGPPEPIEAAVARFFSASCVPGADKGQFPNL CRLCAGTGENKCAFSSQEPYFSYSGAFKCLRDGAGDVAFIRESTVFED LSDEAERDEYELLCPDNTRKPVDKFKDCHLARVPSHAVVARSVNGKED AIWNLLRQAQEKFGKDKSPKFQLFGSPSGQKDLLFKDSAIGFSRVPPR IDSGLYLGSGYFTAIQNLRKSEEEVAARRARVVWCAVGEQELRKCNQW SGLSEGSVTCSSASTTEDCIALVLKGEADAMSLDGGYVYTAGKCGLVP VLAENYKSQQSSDPDPNCVDRPVEGYLAVAVVRRSDTSLTWNSVKGKK SCHTAVDRTAGWNIPMGLLFNQTGSCKFDEYFSQSCAPGSDPRSNLCA LCIGDEQGENKCVPNSNERYYGYTGAFRCLAENAGDVAFVKDVTVLQN TDGNNNEAWAKDLKLADFALLCLDGKRKPVTEARSCHLAMAPNHAVVS RMDKVERLKQVLLHQQAKFGRNGSDCPDKFCLFQSETKNLLFNDNTEC LARLHGKTTYEKYLGPQYVAGITNLKKCSTSPLLEACEFLRK Levels have been shown to increase with leukocyte activation. Therefore, there are increases found during ischemic stroke, following by-pass surgery and after direct stenting in patients with angina. However, no studies that have linked this protein to myocardial ischemia or events leading up to MI. U. Low-Density Lipoprotein Receptor-Related Protein 2

-   Name: LOW-DENSITY LIPOPROTEIN RECEPTOR-RELATED PROTEIN 2 -   IPI ID: IPI00024292 -   UniProtKB/Swiss-Prot ID: P98164 -   Length: 4655 aa, molecular weight: 521958 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Acts together with cubilin to mediate HDL endocytosis (By similarity). May participate in regulation of parathyroid-hormone and para-thyroid-hormone-related protein release. SUBCELLULAR Membrane; Single-pass type I membrane protein. LOCATION Membrane, coated pit. 2. Sequence:

(SEQ ID NO: 40) MDRGPAAVACTLLLALVACLAPASGQECDSAHFRCGSGHCIPADWRCD GTKDCSDDADEIGCAVVTCQQGYFKCQSEGQCIPNSWVCDQDQDCDDG SDERQDCSQSTCSSHQITCSNGQCIPSEYRCDHVRDCPDGADENDCQY PTCEQLTCDNGACYNTSQKCDWKVDCRDSSDEINCTEICLHNEFSCGN GECIPRAYVCDHDNDCQDGSDEHACNYPTCGGYQFTCPSGRCIYQNWV CDGEDDCKDNGDEDGCESGPHDVHKCSPREWSCPESGRCISIYKVCDG ILDCPGREDENNTSTGKYCSMTLCSALNCQYQCHETPYGGACFCPPGY IINHNDSRTCVEFDDCQIWGICDQKCESRPGRHLCHCEEGYILERGQY CKANDSFGEASIIFSNGRDLLIGDIHGRSFRILVESQNRGVAVGVAFH YHLQRVFWTDTVQNKVFSVDINGLNIQEVLNVSVETPENLAVDWVNNK IYLVETKVNRIDMVNLDGSYRVTLITENLGHPRGIAVDPTVGYLFFSD WESLSGEPKLERAFMDGSNRKDLVKTKLGWPAGVTLDMISKRVYWVDS RFDYIETVTYDGIQRKTVVHGGSLIPHPFGVSLFEGQVFFTDWTKMAV LKANKFTETNPQVYYQASLRPYGVTVYHSLRQPYATNPCKDNNGGCEQ VCVLSHRTDNDGLGFRCKCTFGFQLDTDERHCIAVQNFLIFSSQVAIR GIPFTLSTQEDVMVPVSGNPSFFVGIDFDAQDSTIFFSDMSKHMIFKQ KIDGTGREILAANRVENVESLAFDWISKNLYWTDSHYKSISVMRLADK TRRTVVQYLNNPRSVVVHPFAGYLFFTDWFRPAKIMRAWSDGSHLLPV INTTLGWPNGLAIDWAASRLYWVDAYFDKIEHSTFDGLDRRRLGHIEQ MTHPFGLAIFGEHLFFTDWRLGAIIRVRKADGGEMTVIRSGIAYILHL KSYDVNIQTGSNACNQPTHPNGDCSHFCFPVPNFQRVCGCPYGMRLAS NHLTCEGDPTNEPPTEQCGLFSFPCKNGRCVPNYYLCDGVDDCHDNSD EQLCGTLNNTCSSSAFTCGHGECIPAHWRCDKRNDCVDGSDEHNCPTH APASCLDTQYTCDNHQCISKNWVCDTDNDCGDGSDEKNCNSTETCQPS QFNCPNHRCIDLSFVCDGDKDCVDGSDEVGCVLNCTASQFKCASGDKC IGVTNRCDGVFDCSDNSDEAGCPTRPPGMCHSDEFQCQEDGICIPNFW ECDGHPDCLYGSDEHNACVPKTCPSSYFHCDNGNCIHRAWLCDRDNDC GDMSDEKDCPTQPFRCPSWQWQCLGHNICVNLSVVCDGIFDCPNGTDE SPLCNGNSCSDFNGGCTHECVQEPFGAKCLCPLGFLLANDSKTCEDID ECDILGSCSQHCYNMRGSFRCSCDTGYMLESDGRTCKVTASESLLLLV ASQNKIIADSVTSQVHNIYSLVENGSYIVAVDFDSISGRIFWSDATQG KTWSAFQNGTDRRVVFDSSIILTETIAIDWVGRNLYWTDYALETIEVS KIDGSHRTVLISKNLTNPRGLALDPRMNEHLLFWSDWGHHPRIERASM DGSMRTVIVQDKIFWPCGLTIDYPNRLLYFMDSYLDYMDFCDYNGHHR RQVIASDLIIRHPYALTLFEDSVYWTDRATRRVMRANKWHGGNQSVVM YNIQWPLGIVAVHPSKQPNSVNPCAFSRCSHLCLLSSQGPHFYSCVCP SGWSLSPDLLNCLRDDQPFLITVRQHIIFGISLNPEVKSNDAMVPIAG IQNGLDVEFDDAEQYIYWVENPGEIHRVKTDGTNRTVFASISMVGPSM NLALDWISRNLYSTNPRTQSIEVLTLHGDIRYRKTLIANDGTALGVGF PIGITVDPARGKLYWSDQGTDSGVPAKIASANMDGTSVKTLFTGNLEH LECVTLDIEEQKLYWAVTGRGVIERGNVDGTDRMILVHQLSHPWGIAV HDSFLYYTDEQYEVIERVDKATGANKIVLRDNVPNLRGLQVYHRRNAA ESSNGCSNNMNACQQICLPVPGGLFSCACATGFKLNPDNRSCSPYNSF IVVSMLSAIRGFSLELSDHSETMVPVAGQGRNALHVDVDVSSGFIYWC DFSSSVASDNAIRRIKPDGSSLMNIVTHGIGENGVRGIAVDWVAGNLY FTNAFVSETLIEVLRINTTYRRVLLKVTVDMPRHIVVDPKNRYLFWAD YGQRPKIERSFLDCTNRTVLVSEGIVTPRGLAVDRSDGYVYWVDDSLD IIARIRINGENSEVIRYGSRYPTPYGITVFENSIIWVDRNLKKIFQAS KEPENTEPPTVIRDNINWLRDVTIFDKQVQPRSPAEVNNNPCLENNGG CSHLCFALPGLHTPKCDCAFGTLQSDGKNCAISTENFLIFALSNSLRS LHLDPENHSPPFQTINVERTVMSLDYDSVSDRIYFTQNLASGVGQISY ATLSSGIHTPTVIASGIGTADGIAFDWITRRIYYSDYLNQMINSMAED GSNRTVIARVPKPRAIVLDPCQGYLYWADWDTHAKIERATLGGNFRVP IVNSSLVMPSGLTLDYEEDLLYWVDASLQRIERSTLTGVDREVIVNAA VHAFGLTLYGQYIYWTDLYTQRIYRANKYDGSGQIAMTTNLLSQPRGI NTVVKNQKQQCNNPCEQFNGGCSHICAPGPNGAECQCPHEGNWYLANN RKHCIVDNGERCGASSFTCSNGRCISEEWKCDNDNDCGDGSDEMESVC ALHTCSPTAFTCANGRCVQYSYRCDYYNDCGDGSDEAGCLFRDCNATT EFMCNNRRCIPREFICNGVDNCHDNNTSDEKNCPDRTCQSGYTKCHNS NICIPRVYLCDGDNDCGDNSDENPTYCTTHTCSSSEFQCASGRCIPQH WYCDQETDCFDASDEPASCGHSERTCLADEFKCDGGRCIPSEWICDGD NDCGDMSDEDKRHQCQNQNCSDSEFLCVNDRPPDRRCIPQSWVCDGDV DCTDGYDENQNCTRRTCSENEFTCGYGLCIPKIFRCDRHNDCGDYSDE RGCLYQTCQQNQFTCQNGRCISKTFVCDEDNDCGDGSDELMHLCHTPE PTCPPHEFKCDNGRCIEMMKLCNHLDDCLDNSDEKGCGINECHDPSIS GCDHNCTDTLTSFYCSCRPGYKLMSDKRTCVDIDECTEMPFVCSQKCE NVIGSYICKCAPGYLREPDGKTCRQNSNIEPYLIFSNRYYLRNLTIDG YFYSLILEGLDNVVALDFDRVEKRLYWIDTQRQVIERMFLNKTNKETI INHRLPAAESLAVDWVSRKLYWLDARLDGLFVSDLNGGHRRMLAQHCV DANNTFCFDNPRGLALHPQYGYLYWADWGHRAYIGRVGMDGTNKSVII STKLEWPNGITIDYTNDLLYWADAHLGYIEYSDLEGHHRHTVYDGALP HPFAITIFEDTIYWTDWNTRTVEKGNKYDGSNRQTLVNTTHRPFDIHV YHPYRQPIVSNPCGTNNGGCSHLCLIKPGGKGFTCECPDDFRTLQLSG STYCMPMCSSTQFLCANNEKCIPIWWKCDGQKDCSDGSDELALCPQRF CRLGQFQCSDGNCTSPQTLCNAHQNCPDGSDEDRLLCENHHCDSNEWQ CANKRCIPESWQCDTFNDCEDNSDEDSSHCASRTCRPGQFRCANGRCI PQAWKCDVDNDCGDHSDEPIEECMSSAHLCDNFTEFSCKTNYRCIPKW AVCNGVDDCRDNSDEQGCEERTCHPVGDFRCKNHHCIPLRWQCDGQND CGDNSDEENCAPRECTESEFRCVNQQCIPSRWICDHYNDCGDNSDERD CEMRTCHPEYFQCTSGHCVHSELKCDGSADCLDASDEADCPTRFPDGA YCQATMFECKNHVCIPPYWKCDGDDDCGDGSDEELHLCLDVPCNSPNR FRCDNNRCIYSHEVCNGVDDCGDGTDETEEHCRKPTPKPCTEYEYKCG NGHCIPHDNVCDDADDCGDWSDELGCNKGKERTCAENICEQNCTQLNE GGFICSCTAGFETNVFDRTSCLDINECEQFGTCPQHCRNTKGSYECVC ADGFTSMSDRPGKRCAAEGSSPLLLLPDNVRIRKYNLSSERFSEYLQD EEYIQAVDYDWDPKDIGLSVVYYTVRGEGSRFGAIKRAYIPNFESGRN NLVQEVDLKLKYVMQPDGIAVDWVGRHIYWSDVKNKRIEVAKLDGRYR KWLISTDLDQPAAIAVNPKLGLMFWTDWGKEPKIESAWMNGEDRNILV FEDLGWPTGLSIDYLNNDRIYWSDFKEDVIETIKYDGTDRRVIAKEAM NPYSLDIFEDQLYWISKEKGEVWKQNKFGQGKKEKTLVVNPWLTQVR IFHQLRYNKSVPNLCKQICSHLCLLRPGGYSCACPQGSSFIEGSTTEC DAAIELPINLPPPCRCMHGGNCYFDETDLPKCKCPSGYTGKYCEMAFS KGISPGTTAVAVLLTILLIVVIGALAIAGFFHYRRTGSLLPALPKLPS LSSLVKPSENGNGVTFRSGADLNMDIGVSGFGPETAIDRSMAMSEDFV MEMGKQPIIFENPMYSARDSAVKVVQPIQVTVSENVDNKNYGSPINPS EIVPETNPTSPAADGTQVTKWNLFKRKSKQTTNFENPIYAQMENEQKE SVAATPPPSPSLPAKPKPPSRRDPTPTYSATEDTFKDTANLVKEDSEV 3. Alternative Name(s): Megalin; Glycoprotein 330; Short Name=gp330 This protein has not been directly linked to myocardial ischemia or events leading up to MI. V. Prolow Density Lipoprotein Receptor Related Protein 1

-   Name: Prolow density lipoprotein receptor related protein 1 -   IPI ID: IPI00020557 -   UniProtKB/Swiss-Prot ID: Q07954 -   Length: 4544 aa, molecular weight: 504575 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:     -   Function: Endocytic receptor involved in endocytosis and in         phagocytosis of apoptotic cells. Required for early embryonic         development. Involved in cellular lipid homeostasis. Involved in         the plasma clearance of chylomicron remnants and activated         LRPAP1 (alpha 2-macroglobulin), as well as the local metabolism         of complexes between plasminogen activators and their endogenous         inhibitors. May modulate cellular events, such as APP         metabolism, kinase-dependent intracellular signaling, neuronal         calcium signaling as well as neurotransmission.     -   Subcellular location: Low-density lipoprotein receptor-related         protein 1 85 kDa subunit: Cell membrane; Single-pass type I         membrane protein. Membrane>coated pit. Low-density lipoprotein         receptor-related protein 1 515 kDa subunit: Cell membrane;         Peripheral membrane protein; Extracellular side. Membrane>coated         pit. Low-density lipoprotein receptor-related protein 1         intracellular domain: Cytoplasm. Nucleus. Note=After cleavage,         the intracellular domain (LRPICD) is detected both in the         cytoplasm and in the nucleus.         2. Sequence:

(SEQ ID NO: 41) MLTPPLLLLLPLLSALVAAAIDAPKTCSPKQFACRDQITCISKGWRCD GERDCPDGSDEAPEICPQSKAQRCQPNEHNCLGTELCVPMSRLCNGVQ DCMDGSDEGPHCRELQGNCSRLGCQHHCVPTLDGPTCYCNSSFQLQAD GKTCKDFDECSVYGTCSQLCTNTDGSFICGCVEGYLLQPDNRSCKAKN EPVDRPPVLLIANSQNILATYLSGAQVSTITPTSTRQTTAMDFSYANE TVCWVHVGDSAAQTQLKCARMPGLKGFVDEHTINISLSLHHVEQMAID WLTGNFYFVDDIDDRIFVCNRNGDTCVTLLDLELYNPKGIALDPAMGK VFFTDYGQIPKVERCDMDGQNRTKLVDSKIVFPHGITLDLVSRLVYWA DAYLDYIEVVDYEGKGRQTIIQGILIEHLYGLTVFENYLYATNSDNAN AQQKTSVIRVNRFNSTEYQVVTRVDKGGALHIYHQRRQPRVRSHACEN DQYGKPGGCSDICLLANSHKARTCRCRSGFSLGSDGKSCKKPEHELFL VYGKGRPGIIRGMDMGAKVPDEHMIPIENLMNPRALDFHAETGFIYFA DTTSYLIGRQKIDGTERETILKDGIHNVEGVAVDWMGDNLYWTDDGPK KTISVARLEKAAQTRKTLIEGKMTHPRAIVVDPLNGWMYWIDWEEDPK DSRRGRLERAWMDGSHRDIFVTSKTVLWPNGLSLDIPAGRLYWVDAFY DRIETILLNGTDRKIVYEGPELNHAFGLCHHGNYLFWTEYRSGSVYRL ERGVGGAPPTVTLLRSERPPIFEIRMYDAQQQQVGTNKCRVNNGGCSS LCLATPGSRQCACAEDQVLDADGVTCLANPSYVPPPQCQPGEFACANS RCIQERWKCDGDNDCLDNSDEAPALCHQHTCPSDRFKCENNRCIPNRW LCDGDNDCGNSEDESNATCSARTCPPNQFSCASGRCIPISWTCDLDDD CGDRSDESASCAYPTCFPLTQFTCNNGRCININWRCDNDNDCGDNSDE AGCSHSCSSTQFKCNSGRCIPEHWTCDGDNDCGDYSDETHANCTNQAT RPPGGCHTDEFQCRLDGLCIPLRWRCDGDTDCMDSSDEKSCEGVTHVC DPSVKFGCKDSARCISKAWVCDGDNDCEDNSDEENCESLACRPPSHPC ANNTSVCLPPDKLCDGNDDCGDGSDEGELCDQCSLNNGGCSHNCSVAP GEGIVCSCPLGMELGPDNHTCQIQSYCAKHLKCSQKCDQNKFSVKCSC YEGWVLEPDGESCRSLDPFKPFIIFSNRHEIRRIDLHKGDYSVLVPGL RNTIALDFHLSQSALYWTDVVEDKIYRGKLLDNGALTSFEVVIQYGLA TPEGLAVDWIAGNIYWVESNLDQIEVAKLDGTLRTTLLAGDIEHPRAI ALDPRDGILFWTDWDASLPRIEAASMSGAGRRTVHRETGSGGWPNGLT VDYLEKRILWIDARSDAIYSARYDGSGHMEVLRGHEFLSHPFAVTLYG GEVYWTDWRTNTLAKANKWTGHNVTVVQRTNTQPFDLQVYHPSRQPMA PNPCEANGGQGPCSHLCLINYNRTVSCACPHLMKLHKDNTTCYEFKKF LLYARQMEIRGVDLDAPYYNYIISFTVPDIDNVTVLDYDAREQRVYWS DVRTQAIKRAFINGTGVETVVSADLPNAHGLAVDWVSRNLFWTSYDTN KKQINVARLDGSFKNAVVQGLEQPHGLVVHPLRGKLYWTDGDNISMAN MDGSNRTLLFSGQKGPVGLAIDFPESKLYWISSGNHTINRCNLDGSGL EVIDAMRSQLGKATALAIMGDKLWWADQVSEKMGTCSKADGSGSVVLR NSTTLVMHMKVYDESIQLDHKGTNPCSVNNGDCSQLCLPTSETTRSCM CTAGYSLRSGQQACEGVGSFLLYSVHEGIRGIPLDPNDKSDALVPVSG TSLAVGIDFHAENDTIYWVDMGLSTISRAKRDQTWREDVVTNGIGRVE GIAVDWIAGNIYWTDQGFDVIEVARLNGSFRYVVISQGLDKPRAITVH PEKGYLFWTEWGQYPRIERSRLDGTERVVLVNVSISWPNGISVDYQDG KLYWCDARTDKIERIDLETGENREVVLSSNNMDMFSVSVFEDFIYWSD RTHANGSIKRGSKDNATDSVPLRTGIGVQLKDIKVFNRDRQKGTNVCA VANGGCQQLCLYRGRGQRACACAHGMLAEDGASCREYAGYLLYSERTI LKSIHLSDERNLNAPVQPFEDPEHMKNVIALAFDYRAGTSPGTPNRIF FSDIHFGNIQQINDDGSRRITIVENVGSVEGLAYHRGWDTLYWTSYTT STITRHTVDQTRPGAFERETVITMSGDDHPRAFVLDECQNLMFWTNWN EQHPSIMRAALSGANVLTLIEKDIRTPNGLAIDHRAEKLYFSDATLDK IERCEYDGSHRYVILKSEPVHPFGLAVYGEHIFWTDWVRRAVQRANKH VGSNMKLLRVDIPQQPMGIIAVANDTNSCELSPCRINNGGCQDLCLLT HQGHVNCSCRGGRILQDDLTCRAVNSSCRAQDEFECANGECINFSLTC DGVPHCKDKSDEKPSYCNSRRCKKTFRQCSNGRCVSNMLWCNGADDCG DGSDEIPCNKTACGVGEFRCRDGTCIGNSSRCNQFVDCEDASDEMNCS ATDCSSYFRLGVKGVLFQPCERTSLCYAPSWVCDGANDCGDYSDERDC PGVKRPRCPLNYFACPSGRCIPMSWTCDKEDDCEHGEDETHCNKFCSE AQFECQNHRCISKQWLCDGSDDCGDGSDEAAHCEGKTCGPSSFSCPGT HVCVPERWLCDGDKDCADGADESIAAGCLYNSTCDDREFMCQNRQCIP KHFVCDHDRDCADGSDESPECEYPTCGPSEFRCANGRCLSSRQWECDG ENDCHDQSDEAPKNPHCTSPEHKCNASSQFLCSSGRCVAEALLCNGQD DCGDSSDERGCHINECLSRKLSGCSQDCEDLKIGFKCRCRPGFRLKDD GRTCADVDECSTTFPCSQRCINTHGSYKCLCVEGYAPRGGDPHSCKAV TDEEPFLIFANRYYLRKLNLDGSNYTLLKQGLNNAVALDFDYREQMIY WTDVYTTQGSMIRRMHLNGSNVQVLHRTGLSNPDGLAVDWVGGNLYWC DKGRDTIEVSKLNGAYRTVLVSSGLREPRALVVDVQNGYLYWTDWGDH SLIGRIGMDGSSRSVIVDTKITWPNGLTLDYVTERIYWADAREDYIEF ASLDGSNRHVVLSQDIPHIFALTLFEDYVYWTDWETKSINRAHKTTGT NKTLLISTLHRPMDLHVFHALRQPDVPNHPCKVNNGGCSNLCLLSPGG GHKCACPTNFYLGSDGRTCVSNCTASQFVCKNDKCIPFWWKCDTEDDC GDHSDEPPDCPEFKCRPGQFQCSTGICTNPAFICDGDNDCQDNSDEAN CDIHVCLPSQFKCTNTNRCIPGIFRCNGQDNCGDGEDERDCPEVTCAP NQFQCSITKRCIPRVWVCDRDNDCVDGSDEPANCTQMTCGVDEFRCKD SGRCIPARWKCDGEDDCGDGSDEPKEECDERTCEPYQFRCKNNRCVPG RWQCDYDNDCGDNSDEESCTPRPCSESEFSCANGRCIAGRWKCDGDHD CADGSDEKDCTPRCDMDQFQCKSGHCIPLRWRCDADADCMDGSDEEAC GTGVRTCPLDEFQCNNTLCKPLAWKCDGEDDCGDNSDENPEECARFVC PPNRPFRCKNDRVCLWIGRQCDGTDNCGDGTDEEDCEPPTΛHTTHCKD KKEFLCRNQRCLSSSLRCNMFDDCGDGSDEEDCSIDPKLTSCATNASI CGDEARCVRTEKAAYCACRSGFHTVPGQPGCQDINECLRFGTCSQLCN NTKGGHLCSCARNFMKTHNTCKAEGSEYQVLYIADDNEIRSLFPGHPH SAYEQAFQGDESVRIDAMDVHVKAGRVYWTNWHTGTISYRSLPPAAPP TTSNRHRRQIDRGVTHLNISGLKMPRGIAIDWVAGNVYWTDSGRDVIE VAQMKGENRKTLISGMIDEPHAIVVDPLRGTMYWSDWGNHPKIETAAM DGTLRETLVQDNIQWPTGLAVDYHNERLYWADAKLSVIGSIRLNGTDP IVAADSKRGLSHPFSIDVFEDYIYGVTYINNRVFKIHKFGHSPLVNLT GGLSHASDVVLYHQHKQPEVTNPCDRKKCEWLCLLSPSGPVCTCPNGK RLDNGTCVPVPSPTPPPDAPRPGTCNLQCFNGGSCFLNARRQPKCRCQ PRYTGDKCELDQCWEHCRNGGTCAASPSGMPTCRCPTGFTGPKCTQQV CAGYCANNSTCTVNQGNQPQCRCLPGFLGDRCQYRQCSGYCENFGTCQ MAADGSRQCRCTAYFEGSRCEVNKCSRCLEGACVVNKQSGDVTCNCTD GRVAPSCLTCVGHCSNGGSCTMNSKMMPECQCPPHMTGPRCEEHVFSQ QQPGHIASILIPLLLLLLLVLVAGVVFWYKRRVQGAKGFQHQRMTNGA MNVEIGNPTYKMYEGGEPDDVGGLLDADFALDPDKPTNFTNPVYATLY MGGHGSRHSLASTDEKRELLGRGPEDEIGDPLA 3. Alternative Name(s):

-   -   Alpha-2-macroglobulin receptor         -   Short name=A2MR     -   Apolipoprotein E receptor         -   Short name=APOER     -   CD_antigen=CD91         This protein has not been directly linked to myocardial ischemia         or events leading up to MI.         W. Monocyte Differentiation Antigen CD14

-   Name: MONOCYTE DIFFERENTIATION ANTIGEN CD14

-   IPI ID: IPI00029260

-   UniProtKB/Swiss-Prot ID: P08571

-   Length: 375 aa, molecular weight: 40076 Da (of Precursor)     1. Basic Information from UniProtKB/Swiss-Prot Entry:

FUNCTION Cooperates with MD-2 and TLR4 to mediate the innate immune response to bacterial lipopolysaccharide (LPS). Acts via MyD88, TIRAP and TRAF6, leading to NF-kappa-B activation, cytokine secretion and the inflammatory response. Up-regulates cell surface molecules, including adhesion molecules. SUBCELLULAR Cell membrane; Lipid-anchor, GPI-anchor. LOCATION 2. Sequence:

(SEQ ID NO: 42) MERASCLLLLLLPLVHVSATTPEPCELDDEDFRCVCNFSEPQPDWSEA FQCVSAVEVEIHAGGLNLEPFLKRVDADADPRQYADTVKALRVRRLTV GAAQVPAQLLVGALRVLAYSRLKELTLEDLKITGTMPPLPLEATGLAL SSLRLRNVSWATGRSWLAELQQWLKPGLKVLSIAQAHSPAFSCEQVRA FPALTSLDLSDNPGLGERGLMAALCPHKFPAIQNLALRNTGMETPTGV CAALAAAGVQPHSLDLSHNSLRATVNPSAPRCMWSSALNSLNLSFAGL EQVPKGLPAKLRVLDLSCNRLNRAPQPDELPEVDNLTLDGNPFLVPGT ALPHEGSMNSGVVPACARSTLSVGVSGTLVLLQGARGFA 3. Alternative Name(s): Myeloid Cell-Specific Leucine-Rich Glycoprotein; CD_Antigen=CD14 Monocytes and T-cells play an important role in the development of atherosclerotic coronary artery disease. C14 is located on the monocytes and, therefore, changes to this protein can and have been linked to alterations to monocytes (including with coronary artery disease). However, this protein has not been measured in serum in context to myocardial ischemia or events leading up to a MI. X. Peroxiredoxin-2

-   Name: Peroxiredoxin-2 -   IPI ID: IPI00027350 -   UniProtKB/Swiss-Prot ID: P32119; PRDX2_HUMAN; M. -   Length: 198 aa, molecular weight: 21892 Da, CRC64 checksum:     1AC781D908B32B46     1. Basic Information from UniProtKB/Swiss-Prot Entry:

Function Involved in redox regulation of the cell. Reduces peroxides with reducing equivalents provided through the thioredoxin system. It is not able to receive electrons from glutaredoxin. May play an important role in eliminating peroxides generated during metabolism. Might participate in the signaling cascades of growth factors and tumor necrosis factor-alpha by regulating the intracellular concentrations of H₂O₂. Catalytic 2 R′—SH + ROOH = R′—S—S—R′ + H₂O + ROH. activity Subunit Homodimer; disulfide-linked, upon oxidation. May be structure found as a toroid-shaped decamer composed of 5 dimers, depending on pH and calcium concentration. Interacts with TIPIN. Subcellular Cytoplasm. location Miscella- The active site is the redox-active Cys-51 oxidized to Cys- neous SOH. Cys-SOH rapidly reacts with Cys-172-SH of the other subunit to form an intermolecular disulfide with a concomitant homodimer formation. The enzyme may be subsequently regenerated by reduction of the disulfide by thioredoxin. Inactivated upon oxidative stress by overoxidation of Cys- 51 to Cys-SO₂H and Cys-SO₃H. Cys-SO₂H is retroreduced to Cys-SOH after removal of H₂O₂, while Cys-SO₃H may be irreversibly oxidized. Sequence Belongs to the ahpC/TSA family. similarities Contains 1 thioredoxin domain. 2. Sequence:

(SEQ ID NO: 43) MASGNARIGKPAPDFKATAVVDGAFKEVKLSDYKGKYVVLFFYPLDFT FVCPTEIIAFSNRAEDFRKLGCEVLGVSVDSQFTHLAWINTPRKEGGL GPLNIPLLADVTRRLSEDYGVLKTDEGIAYRGLFIIDGKGVLRQITVN DLPVGRSVDEALRLVQAFQYTDEHGEVCPAGWKPGSDTIKPNVDDSKE YFSKHN 3. Alternative Name(s): Thioredoxin Peroxidase 1

-   -   Thioredoxin-dependent peroxide reductase 1     -   Thiol-specific antioxidant protein         -   Short name=TSA     -   PRP     -   Natural killer cell-enhancing factor B         -   Short name=NKEF-B             This protein has been found to increase in the serum of a             number diseases but none are cardiac related. This protein,             to date, has not been shown to be increased in myocardial             ischemia or events leading to MI.             Y. NCOR2 CTG26 Alternate Open Reading Frame

-   Name: CTG26 alternate open reading frame (Fragment)

-   IPI ID: IPI00006659.3

1. Basic Information: Fragment

2. Sequence:

(SEQ ID NO: 44) SFSSMEASSALCWGVMASSLLASLAIERVMRPLRLPWLLAVLRPLEAT ASFSSLSSPEVSSVFSLRRSSLSFSTSGFSSSFSASFSFSFSSFSSWL LRGMGCCCCCCCCCCCCCCCCWLLPRRR This protein has not be linked to myocardial ischemia or events leading up to MI.

Example V Validation Studies

Antibodies to two or more epitopes on each protein will be generated and used to develop a sandwich ELISA assay (as single or multiplex) that is specific and sensitive for the analyte. The analyte will either be peptide, protein fragment or protein and will be used to generate standard curve. Analysis will be carried out using conventional ELISA or on a Luminex or Mesoscale platform. Assays will be carried out at least in duplicate. For MRM assays, peptides (generated most likely by trypsin, chymotrypsin or Lys C) that are unique to the protein of interest and showing high MS signal response (prototypic peptides) which will help maximize the sensitivity of the assay. 2. Selection of predominant peptide fragments specific (MS/MS) for the parent peptide (useful MRM transition). 3. For each peptide-fragment pair, optimization of specific MS parameters (e.g. the collision energy) to maximize the signal response/sensitivity. 4. Validation of the MRM assay to confirm peptide identity, e.g. by acquiring a full MS2 spectrum of the peptide in the triple quadrupole MS instrument used for MRM. 5. Extraction of the final “coordinates” of the MRM assay, including the selected peptide and peptide fragments, the corresponding mass-to-charge ratios, the fragment intensity ratios, the associated collision energy, and the chromatographic elution time to be optionally used in time-constrained MRM analyses. We will add isotopically labeled internal peptide standards (with known concentrations determined by amino acid analysis) to facilitate absolute quantitation of selected peptides. Assays will be performed on a triple quadruple mass spectrometer at least in duplicate.

From the foregoing description, one skilled in the art can easily ascertain the essential characteristics of this invention, and without departing from the spirit and scope thereof, can make changes and modifications of the invention to adapt it to various usage and conditions and to utilize the present invention to its fullest extent. The preceding preferred specific embodiments are to be construed as merely illustrative, and not limiting of the scope of the invention in any way whatsoever. The entire disclosure of all applications, patents, and publications (including provisional patent application 61/128,688, filed May 23, 2008) cited above and in the figures are hereby incorporated in their entirety by reference. 

We claim:
 1. A method for determining if a subject has myocardial ischemia, comprising a) providing a blood sample obtained from a subject suspected of having myocardial ischemia; b) determining in the sample the amount of one or more of the following proteins: i) Lumican and/or ii) Extracellular matrix protein 1 and/or iii) Carboxypeptidase N; and c) comparing the amount(s) of the protein(s) to a baseline value that is indicative of the amount of the protein in a subject that does not have myocardial ischemia, wherein a statistically significantly increased amount of the protein(s) compared to the baseline value is indicative of myocardial ischemia.
 2. A method for determining if a subject has myocardial ischemia, comprising a) providing a blood sample obtained from a subject suspected of having myocardial ischemia; b) determining in the sample the amount of four or more of the following proteins: i) Lumican, and/or ii) Extracellular matrix protein 1, and/or iii) Carboxypeptidase N, and/or iv) Angiogenin, and/or v) Semenogelin, and/or vi) Long palate, lung and nasal epithelium carcinoma-associated protein 1, and/or vii) Perioxiredoxin isoform 2, and/or viii) Syntaxin 3, and/or ix) S100 isoform A7, and/or x) S100 isoform A8, and/or xi) S100 isoform A9, and/or xii) Sortilin-related receptor, and/or xiii) Catalase, and/or xiv) Low density lipoprotein receptor related protein 1, and/or xv) Low density lipoprotein receptor related protein
 2. c) comparing the amount(s) of the protein(s) to a baseline value that is indicative of the amount of the protein in a subject that does not have myocardial ischemia, wherein a statistically significantly increased amount of the protein(s) compared to the baseline value is indicative of myocardial ischemia.
 3. The method of claim 1, further comprising determining in the sample the amount, compared to a baseline value, of one or more of the following proteins: iv) Angiogenin, and/or v) Semenogelin, and/or vi) Long palate, lung and nasal epithelium carcinoma-associated protein 1, wherein a statistically significantly increased amount of the protein(s) compared to the baseline value is indicative of myocardial ischemia that was caused by metabolic demand.
 4. The method of claim 1, further comprising determining in the sample the amount, compared to a baseline value, of one or more of the following proteins: vii) Perioxiredoxin isoform 2, and/or viii) Syntaxin 3, and/or ix) S100 isoform A7, and/or x) S100 isoform A8, and/or xi) S100 isoform A9, and/or xii) Sortilin-related receptor, and/or xiii) Catalase, and/or xiv) Low density lipoprotein receptor related protein 1, and/or xv) Low density lipoprotein receptor related protein 2, wherein a statistically significantly increased amount of the protein(s) compared to the baseline value is indicative of myocardial ischemia that was caused by coronary blood vessel blockage.
 5. The method of claim 1, further comprising determining in the sample the amount(s) of one or more of the following additional proteins: xvi) Hepatocyte growth factor activator, and/or xvii) Alpha-2-HS-glycoprotein, and/or xviii), Insulin like growth factor protein 6, and/or xix) Galectin-7, and/or xx) Hornerin, and/or xxi) Proteoglycan-4, and/or xxii) Profilaggrin (also referred to as Filaggrin), and/or xxiii) Vitamin D binding protein, and/or xxiv) C4b-binding protein alpha chain, and/or xxv) Thyroxine binding globulin, and/or xxvi) Alpha-2-glycoprotein 1, zinc, and/or xxvii) Serine 3 protease, and/or xxviii) Caspase 14, and/or xxix) Desmogelin, and/or xxx) Kininogen-1, and/or xxxi) Hepatocyte growth factor like protein.
 6. The method of claim 1, further comprising measuring the amount of one or more of the cardiac specific isoforms of troponin I (TnI) or troponin T (TnT), CK-MB, or myoglobin, wherein a statistically significant increase of the one or more markers is further indicative that the subject has myocardial ischemia.
 7. The method of claim 1, wherein the sample is from blood.
 8. The method of claim 1, wherein the sample is from cardiac tissue, urine or sweat.
 9. The method of claim 1, wherein the determining of the amount of a protein is accomplished by a method comprising binding the protein to an antibody that is specific for the protein, under conditions effective for specific binding of the protein to the antibody.
 10. The method of claim 9, wherein the method is an ELISA.
 11. The method of claim 9, wherein the antibody is contacted with a histological preparation of a biopsy sample from cardiac tissue, and is visualized by immunohistochemical staining.
 12. The method of claim 1, wherein the determining of the amount of a protein is accomplished by mass spectrometry.
 13. The method of claim 1, further comprising, if the subject is determined to be likely to have myocardial ischemia, making a decision to treat the subject aggressively for the ischemia, and if the subject is determined not to be likely to have myocardial ischemia, making a decision not to treat the subject aggressively for the ischemia.
 14. The method of claim 1, which is a method for following the progression of ischemia in the subject.
 15. The method of claim 1, wherein the detection is carried out both before or at approximately the same time as, and after, the administration of a treatment, and which is a method for determining the effectiveness of the treatment.
 16. The method of claim 1, wherein the subject is human.
 17. A method for treating a subject suspected of having myocardial ischemia, comprising determining by the method of claim 1 whether the subject is likely to have myocardial ischemia and, if the subject is determined to be likely to have myocardial ischemia, treating the subject aggressively for the ischemia, and if the subject is determined not to be likely to have myocardial ischemia, treating the subject aggressively for the ischemia. 